Download Packaged Water Chiller with Screw Compressors
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Installation and Maintenance Manual IM 549 Group: Chiller Part Number: 5714335Y Date: August 1996 Packaged Water Chiller with Screw Compressors Models: ALS125A thru 204A ALS205A thru 280A ALS300A thru 380A PFS150A thru 200A ® ©1996 McQuay International Table of Contents Introduction ....................................................................... 4 General Description ........................................................... 4 Control Panel Features ....................................................... 5 Software Identification ....................................................... 5 Controller Layout ............................................................... 6 Component Data ............................................................... 6 Microprocessor Control Board ...................................... 6 Analog/Digital Input Board (ADI Board) ........................ 7 Output Board ................................................................. 7 Electronic Expansion Valve Board (EXV Board) ............ 7 Analog Output Board (AOX Board) ............................... 8 Keypad/Display .............................................................. 8 Sensors And Transducers ................................................... 9 Standard Sensors .......................................................... 9 Optional Sensor Packages ............................................ 9 Thermistor Sensors ....................................................... 9 Pressure Transducers .................................................. 11 Liquid Presence Sensor .............................................. 11 Sensor Locations ............................................................... 12 Analog Inputs ............................................................... 13 Digital Inputs ................................................................ 15 Analog Outputs ............................................................ 16 Digital Outputs ............................................................. 17 Installation ....................................................................... 18 Controller Calibration ................................................... 18 Field Wiring .................................................................. 18 Analog Sensors and Transducers .......................... 18 Digital Input Signals ................................................ 18 Digital Outputs ........................................................ 18 Interlock Wiring ....................................................... 18 External Alarm Circuit ............................................. 18 Power Wiring ........................................................... 18 Power Supplies ....................................................... 18 Demand Limit and Chilled Water Reset Signals .... 18 Communication Ports ............................................. 18 Modem Kit ............................................................... 19 Telephone Line for Remote Modem Access .......... 19 Unit Sequence of Operation ............................................. 19 Off Conditions .............................................................. 19 Start-up ........................................................................ 19 Waiting for Load .......................................................... 19 Start Requested ........................................................... 19 Prepurge ...................................................................... 19 Opened EXV ................................................................. 20 Low Ambient Start ....................................................... 20 Cool Stage (0 through 8) ............................................. 20 Compressor Control ......................................................... 20 Normal Compressor Staging Logic ............................. 20 Project-Ahead Calculation .......................................... 21 Interstage Timer ........................................................... 21 Anti-Cycle Timer .......................................................... 21 Compressor Heater Control ........................................ 21 Lead-Lag Of Refrigerant Circuits ..................................... 22 Automatic Lead-Lag .................................................... 22 Manual Lead-Lag ......................................................... 22 2 Electronic Expansion Valve .............................................. 22 Overview ...................................................................... 22 Exv Superheat Control ................................................ 22 Forced EXV Position Change ...................................... 22 EXV Evaporator Pressure Control ............................... 23 Chilled Water Reset Options ........................................... 23 Chilled Water Reset (Remote 4-20mA) ....................... 23 Ice Mode ...................................................................... 23 Network Reset ............................................................. 23 Return Water Reset ..................................................... 24 Remote Demand Limit ................................................. 24 Network Demand Limit ................................................ 24 Soft Loading ................................................................ 24 Max Pull Down ............................................................. 24 Condenser Fan Control ................................................... 24 Condenser Fan Staging ............................................... 24 Head Pressure Control ................................................ 24 Lift Pressure Calculation ............................................. 25 Lift Pressure Dead Band ............................................. 25 Condenser Fan Stage Up ............................................ 26 High Pressure Stage Up .............................................. 26 Condenser Fan Stage Down ....................................... 26 SpeedTrol Logic .......................................................... 26 Pumpdown ....................................................................... 26 Automatic Pumpdown ................................................. 26 Manual Pumpdown ................................................. 27 Service Pumpdown ................................................. 27 Safety Systems .................................................................. 27 System Alarms ............................................................. 27 Loss of Chw Flow ........................................................ 27 Bad Phase/Voltage ................................................. 27 No 5VDC @AI#5 ...................................................... 27 Chilled Water Freeze Protect .................................. 27 Bad Leaving Chilled Water Sensor ......................... 27 Circuit Alarms .............................................................. 27 Mechanical High Pressure ...................................... 27 High Condenser Pressure ....................................... 27 High Condenser Pressure Stage Down .................. 27 High Condenser Pressure Stage Hold ................... 28 No Liquid Start ........................................................ 28 No Liquid Run ......................................................... 28 Can’t Start - Low Evaporator Pressure .................. 28 Low Evaporator Pressure ....................................... 28 Freeze Protect Stage Down and Freeze Stat Protect ................................................. 28 Failed Pre-Purge ..................................................... 28 Failed EXV or Low Refrigerant Charge ................... 28 Failed Low Ambient Start ....................................... 28 Can't Pump Down ................................................... 28 Bad Evaporator Pressure Sensor ........................... 28 Bad Condenser Pressure Sensor ........................... 28 Wait Flooded ........................................................... 28 Wail Flooded ........................................................... 28 MicroTech Controller Test Procedures ........................... 29 Service Test (Digital Outputs) ...................................... 29 Service Test (Digital Inputs) ......................................... 29 IM 549 Keypad/Display ............................................................... 29 Overview ...................................................................... 29 Status Category ........................................................... 29 Control Category ......................................................... 29 Alarm Category ............................................................ 30 Display Format ............................................................. 30 MicroTech Component Test Procedures & ALS Units ...... 30 Status LED Diagnostics ............................................... 30 Red LED Remains On ............................................. 30 Red and Green LEDs Off ........................................ 30 Troubleshooting Power Problems ............................... 30 Troubleshooting Communications Problems ............. 31 Troubleshooting the Keypad/Display Interface .......... 31 Display is Hard to Read .......................................... 31 Back Light Not Lit ................................................... 31 Display Is Blank or Garbled .................................... 31 Troubleshooting Analog Inputs ................................... 32 Analog Input Not Read by the MCB ....................... 32 Troubleshooting Digital Inputs .................................... 32 Digital Input Not Read by the MCB ........................ 32 Troubleshooting Analog Outputs ................................ 32 Analog Output Device Is Not Operating Correctly ... 32 Troubleshooting Output Boards .................................. 33 One LED Out ........................................................... 33 All LEDs Out ............................................................ 33 LED Lit, Output Not Energized ............................... 33 Output Energized, LED Not Lit ............................... 33 Contact Chatter ...................................................... 33 IM 549 Troubleshooting Solid-State Relays ............................ 34 MCB Replacement ...................................................... 34 Connecting The Communications Trunk .................... 35 Communications Cable Check ............................... 35 Level-1 Controller Connection ................................ 35 Level-2 Controller Connection ................................ 35 Keypad Key Functions ..................................................... 36 Keypad Password ........................................................ 36 Category Group ........................................................... 36 Menu Group ................................................................. 37 Item Group ................................................................... 37 Action Group ................................................................ 37 Example of Keypad Operation .................................... 37 Personal Computer Specification ..................................... 37 MicroTech Menu Structure ............................................. 38 Status Menus ............................................................... 38 Control Menus ............................................................. 38 Alarm Menus ................................................................ 38 Schematics And Drawings ................................................ 60 Control Cabinet Layout ............................................... 60 Wiring Legend .............................................................. 63 PFS Unit Control .......................................................... 64 PFS 8-Stage Output .................................................... 65 PFS MicroTech ............................................................ 66 ALS Unit Control .......................................................... 67 ALS 8-Stage Output .................................................... 68 ALS MicroTech ............................................................ 69 ALS Field Wiring .......................................................... 70 3 Introduction This manual provides installation, setup and troubleshooting information for the MicroTech controller provided on McQuay screw compressor chillers. Please refer to installation manual IM548 for unit application information as well as water and refrigerant piping details. All operating descriptions contained in this manual are based on MicroTech controller software version SC2-X18B, SC3XX19 and SC4XX19A. Chiller operating characteristics and menu selections may vary with other versions of controller software. Contact McQuayService for software update information. ! ! The McQuay MicroTech control panel contains static sensitive components. A static discharge while handling electronic circuit boards may cause damage to the components. To prevent such damage during service involving board replacement, McQuay recommends discharging any static electrical charge by touching the bare metal inside the panel before performing any service work. CAUTION This equipment generates, uses and can radiate radio frequency energy and if not installed and used in accordance with the instructions manual, may cause interference to radio communications. It has been tested and found to comply with the limits for a class A digital device, pursuant to part 15 of the FCC rules. These limits are designed to provide reasonable protection against harmful interference when the equipment is operated in a commercial environment. Operation of this equipment in a residential area is likely to cause harmful interference in which case the user will be required to correct the interference at his own expense. McQuay International disclaims any liability resulting from any interference or for the correction thereof. CAUTION ! CAUTION Excessive moisture in the control panel can cause hazardous working conditions and improper equipment operation. When servicing equipment during rainy weather conditions, the electrical devices and MicroTech components housed in the main control panel must be protected. The MicroTech controller is designed to operate within an ambient temperature range of minus 40 to plus 185°F and a maximum relative humidity of 95% (non-condensing). General Description The MicroTech Unit Control Panel, available on all McQuay ALS and PFS products, contains a Model 250 Microprocessor based controller which provides all monitoring and control functions required for the safe, efficient operation of the unit. The operator can monitor all operating conditions by using the panel’s built in 2 line by 16 character display and keypad or by using an IBM compatible computer running McQuay Monitor software. In addition to providing all normal operating controls, the MicroTech controller monitors all safety devices on the unit and will shut the system down and close a set of alarm contacts if an alarm condition develops. 4 Important operating conditions at the time an alarm occurs are retained in the controller’s memory to aid in troubleshooting and fault analysis. The system is protected by a password scheme which only allows access by authorized personnel. A valid password must be entered into the panel keypad by the operator before any set points may be altered. Table 1. Unit Identification ALS PFS Air Cooled Chiller with Screw Compressors Water Cooled Chiller with Screw Compressors IM 549 Control Panel Features ● Flexible control of leaving chilled water with convenient reset capability. ● Enhanced head pressure control on air cooled units resulting in increased total unit SEER. ● ● condition occurred. In addition, the operating conditions that existed at the instant of shutdown can be recalled to aid in isolating the cause of the problem. ● Convenient, easy to read 2 line by 16 character display for plain English readout of operating temperatures and pressures, operating modes or alarm messages. Soft loading feature to reduce electrical consumption and peak demand charges during chilled water loop pulldown. ● Keypad adjustment of unit safeties such as low water temperature cutout, high pressure cutout, suction pressure cutout, and freeze protection. The operator can use the keypad to monitor various operating conditions, set points or alarm messages. Easy integration into building automation systems via separate 4-20 milliamp signals for chilled water reset and demand limiting. McQuay’s Open Protocol feature is fully supported. ● Flexible internal time clock for on/off scheduling. ● Communications capabilities for local system monitoring, changing of set points, trend logging, remote reset, alarm and event detection, via IBM compatible PC. The optional modem kit supports the same features from an off-site PC running McQuay Monitor software. ● Special service modes may be used to override automatic unit staging during system checkout and service. ● Security password protection against unauthorized changing of set points and other control parameters. ● Complete plain English diagnostics to inform the operator of system warnings and alarms. All alarms are time and date stamped so there is no guessing of when the alarm Software Identification The software “version” is the 5th & 6th digit of the software number. In the example, the version is “17” and the revision to the software is “G”. Revisions are released in alphabetical order. Controller software is factory installed and tested in each panel prior to shipment. The software is identified by a program code which is printed on a small label attached to the controller. The software version may also be displayed on the keypad/display by viewing the last menu item in the Misc. Setup menu. SC Hardware 3 2 E 19 A Software Screw Chiller Revision Number of Compressors Version Refrigerant Type 2 = R22 Type 3 = R134a IM 549 English 5 Controller Layout knockouts provided and be terminated on field wiring terminal strips. The standard ALS keypad/display is located inside the control cabinet for protection from the weather while the PFS Keypad/Display is accessible through the exterior of the control cabinet. See Figure 1 for typical control cabinet layout. All major MicroTech components are mounted inside the control section side of the unit’s control cabinet. The individual components are interconnected by ribbon cables, shielded multi-conductor cables or discrete wiring. Power for the system is provided by transformers T-2 and T-4. All field wiring must enter the control cabinet through the Figure 1. Typical control cabinet layout — 2 compressor unit FB6 Keypad FB7 FB9 FB8 FB5 FB10 FB11 T1 Mech. relays GRD F1 CB F2 M11 NB ADX GFP S M14 PB1 M24 TB2 GFP R OL5 OL1 CB5 CB1 M5 M1 OL2 OL6 CB2 CB6 M2 M6 TB3 High voltage wireway M22 PVM Low voltage wireway GD1 Low voltage wireway T8 RES1 Fax alarm option T2 T4 High voltage wireway TB5 Output board GD2 TB4 Low voltage wireway Modem Low voltage wireway M25 CT1 Low voltage wireway ADI M15 M23 High voltage wireway EXV M21 MDBI M12 M13 T10 T7 C1 C2 SC Component Data Microprocessor Control Board (MCB1) Figure 2. MCB1 The Model 250 Microprocessor Control Board contains the electronic hardware and software required to monitor and control the unit. It receives input from the ADI Board and sends commands to the Output Board to maintain the unit’s optimum operating mode for the current conditions. Status lights are mounted on the control board to indicate the operating condition of the microprocessor. 6 IM 549 Analog/Digital Input Board (ADI Board) The ADI Board provides low voltage power for the temperature and pressure sensors. It also provides electrical isolation between the Microprocessor Control Board and all 24V switch inputs. LEDs are furnished on the board to give a visual indication of the status of all digital inputs. All analog and digital signals from sensors, transducers and switches are received by the ADI Board and then sent to the Microprocessor Control Board for interpretation. Figure 3. ADI Output Board The Output Board contains up to 24 solid state relays which are used to control all compressors, condenser fans, solenoid valves and alarm annunciation. It receives control signals from the Microprocessor Control Board through a 50 conductor ribbon cable. Figure 4. Output board Electronic Expansion Valve Board (EXV Board) Each EXV Board will directly control up to two electronic expansion valves. The boards may be cascaded together for units with more than two EXV’s. Control instructions for the board are generated by the M250 controller. Figure 5. EXV board IM 549 7 Analog Output Board (AOX Board) (With Optional SpeedTrol) The AOX Board converts control instructions from the M250’s expansion bus into an analog control signal suitable for driving a variable speed condenser fan. Each AOX Board is factory set via jumper to provide an output signal of 0 - 10 VDC. Figure 6. AOX board Keypad/Display The Keypad/Display is the primary operator interface to the unit. All operating conditions, system alarms and set points can be monitored from this display and all adjustable set points can be modified from this keyboard if the operator has entered a valid operator password. Figure 7. Keypad display 8 IM 549 Sensors and Transducers Standard Sensors Evaporator Leaving Water Temperature Evaporator Refrigerant Pressure, Circuit #1, 2, 3 & 4 Condenser Refrigerant Pressure, Circuit #1, 2, 3 & 4 Saturated Suction Temperature, Circuit #1, 2, 3 & 4 Liquid Line Temperature, Circuit #1, 2, 3 & 4 (Provides direct display of subcooling and superheat) Entering Evaporator Water Temperature Ambient O.A. Temperature Optional Sensor Packages Water cooled units only: Air and water cooled units: Entering Condenser Water Temperature Leaving Condenser Water Temperature Percent Unit Amps on 2 Compressor Units (Percent total unit amperage including compressors and condenser fans. Does not include externally powered equipment such as water pumps.) Percent Compressor Amps On 3 Compressor Units And Percent Circuit Amps (1 & 3, 2 & 4) On 4 Compressor Units. Thermistor Sensors MicroTech panels use a negative temperature coefficient thermistor for temperature sensing. A normal sensor will measure 3000 ohms at 77°F. Figure 8. Thermistor sensor Stainless steel tubing Potting Shielded cable Thermistor IM 549 9 Table 2. MicroTech thermistors 10 °F Ohms Volts °F Ohms Volts °F Ohms Volts 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 16,104 15,627 15,166 14,720 14,288 13,871 13,467 13,076 12,698 12,333 11,979 11,636 11,304 10,983 10,672 10,371 10,079 9797 9523 9258 9002 8753 8512 8278 8052 7832 7619 7413 7213 7019 6831 6648 6471 6299 6133 5971 5814 5662 5514 5371 5231 5096 4965 4714 4594 4477 4363 4253 4146 4042 3941 3842 3748 3655 3565 3477 3392 3309 3328 3150 3074 4.145 4.124 4.102 4.080 4.057 4.034 4.011 3.988 3.964 3.940 3.915 3.890 3.865 3.839 3.814 3.788 3.761 3,734 3.707 3.608 3.653 3.625 3.597 3.569 3.540 3.511 3.482 3.453 3.424 3.394 3.365 3.335 3.305 3.274 3.244 3.213 3.183 3.152 3.121 3.078 3.059 3.028 2.996 2.934 2.902 2.871 2.839 2.808 2.777 2.745 2.714 2.682 2.651 2.620 2.589 2.558 2.527 2.496 2.465 2.434 2.404 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 101 102 103 104 105 106 107 108 109 110 111 112 113 114 115 116 117 118 119 121 122 123 124 125 126 127 128 129 130 131 132 133 134 135 136 137 138 3000 2927 8357 2789 2723 2658 2595 2534 2474 2416 2360 2305 2251 2199 2149 2099 2051 2004 1959 1914 1871 1829 1788 1747 1708 1670 1633 1597 1562 1528 1494 1461 1430 1398 1368 1339 1310 1282 1254 1228 1201 1176 1151 1103 1080 1058 1036 1014 993 973 953 933 914 895 877 859 842 825 809 792 777 2.373 2,343 2.313 2.283 2.253 2.223 2.194 2.164 2.135 2.106 2.077 2.049 2.020 1.992 1.965 1.937 1.909 1.882 1.855 1.828 1.802 1.775 1.750 1.724 1.698 1.673 1.648 1.624 1.600 1.576 1.552 1.528 1.505 1.482 1.459 1.437 1.415 1.393 1.371 1.350 1.328 1.308 1.287 1.247 1.227 1.208 1.189 1.170 1.151 1.133 1.115 1.076 1.079 1.062 1.045 1.028 1.012 0.995 0.980 0.963 0.948 139 140 141 142 143 144 145 146 147 148 1490 150 151 152 153 154 155 156 157 153 159 160 161 162 163 164 165 166 167 168 169 170 171 172 173 174 175 176 177 178 179 180 181 183 184 185 186 187 188 189 190 191 192 193 194 195 196 197 198 199 200 761 746 731 717 703 689 676 662 649 637 625 613 601 589 578 567 556 546 535 525 516 506 496 487 478 469 461 452 444 436 428 420 413 405 398 391 384 377 370 364 357 351 345 333 327 321 316 310 305 299 294 289 284 280 275 270 266 261 257 252 248 0.932 0.917 0.902 0.888 0.874 0.859 0.846 0.831 0.818 0.805 0.792 0.779 0.766 0.753 0.741 0.729 0.717 0.706 0.694 0.683 0.673 0.661 0.650 0.640 0.629 0.619 0.610 0.599 0.590 0.580 0.571 0.561 0.553 0.544 0.535 0.527 0.518 0.510 0.501 0.494 0.485 0.478 0.471 0.456 0.448 0.441 0.435 0.427 0.421 0.413 0.407 0.400 0.394 0.389 0.382 0.376 0.371 0.364 0.359 0.353 0.348 IM 549 Pressure Transducers These transducers are selected for a specific operating range and provide an output signal which is proportional to the sensed pressure. The typical range for evaporator sensors is 0 to 150 psig with a resolution of 0.1 psig. Condenser pressure sensors have a range of 0 to 450 psi and a resolution of 0.5 psig. The pressure transducers require an external 5 VDC power supply to operate which is provided by the MicroTech controller. This connection should not be used to power any additional devices. Figure 9. Red dot – condenser Blue dot – evaporator Liquid Presence Sensor The presence of liquid refrigerant is determined by a liquid level sensor mounted at the liquid injection port in the compressor casting. Whenever the glass prism sensor tip is in contact with liquid, the sensor output signal will be high (>7VAC). If no liquid is detected, the output will be low (0VAC). Figure 10. IM 549 11 Sensor Locations – 2 Compressor Unit Table 3. Sensor Part Number Description S00 S01 S02 S03 S04 Evaporator Leaving Water Temperature Evaporator Pressure Transducer Circuit #1 Evaporator Pressure Transducer Circuit #2 Condenser Pressure Transducer Circuit #1 Condenser Pressure Transducer Circuit #2 605830-03 658168B-011 658168B-011 658168B-021 658168B-021 S06 Evaporator Water Temperature Reset (Outdoor Air or Zone) S07 S08 Demand Limit Evaporator Entering Water Temperature N/A 705830B-02 S09 Condenser Entering Water Temperature (or Outside Air) 705830B-01 S11 S12 S13 S14 S15 Total Unit Amps Suction Temperature Circuit #1 Suction Temperature Circuit #2 Liquid Line Temperature Circuit #1 Liquid Line Temperature Circuit #2 N/A 705830B-02 705830B-01 705830B-01 705830B-02 Figure 11. S02 S13 S04 S15 Inside of control box on power & control panels S11 Out S09 S00 12 S08 S12 S03 S01 S14 Back of control box IM 549 Analog Inputs Analog inputs are used to read the various temperature and pressure sensors installed on the chiller as well as any customer supplied 4-20mA reset signals. The controller’s internal regulated 5 VDC and 12 VDC supplies provide the correct operating voltage for the sensors. Table 4a. Analog inputs — 2 compressor units No. Description S00 S01 S02 S03 S04 S05 S06 S07 S08 S09 S10 S11 S12 S13 S14 S15 Evaporator Leaving Water Temp Evap Pressure Transducer, Cir #1 Evap Pressure Transducer, Cir #2 Cond Pressure Transducer, Cir #1 Cond Pressure Transducer, Cir #2 Transducer Power Voltage Ratio Reset-Evap Water Temperature Demand Limit Entering Evaporator Water Temp O.A.T. (Ent Cond Water Temp) Condenser Leaving Water Temp Percent Unit Amps Suction Temperature Circuit #1 Suction Temperature Circuit #2 Liquid Line Temperature Circuit #1 Liquid Line Temperature Circuit #2 Table 4b. Analog inputs — 3 compressor units Sensor Number S00 S01 S02 S03 S04 S06 S07 S08 S09 S10 S11 S12 S13 S14 S15 S16 S17 S18 S19 S20 S21 S22 S23 IM 549 Description Evaporator Leaving Water Temperature Low Pressure Transducer Circuit #1 Low Pressure Transducer Circuit #2 High Pressure Transducer Circuit #1 High Pressure Transducer Circuit #2 Evaporator Water Temperature Reset (Field Supplied) Demand Limit (Field Supplied) Evaporator Entering Water Temperature Outside Air Temperature Percent Circuit Amps Circuit #1 Percent Circuit Amps Circuit #2 Suction Temperature Circuit #1 Suction Temperature Circuit #2 Liquid Line Temperature Circuit #1 Liquid Line Temperature Circuit #2 Low Pressure Transducer Circuit #3 High Pressure Transducer Circuit #3 Suction Temperature Circuit #3 Liquid Line Temperature Circuit #3 Discharge Temperature Circuit #1 Discharge Temperature Circuit #2 Discharge Temperature Circuit #3 Percent Circuit Amps Circuit #3 Sensor Location Leaving chilled water nozzle Common cir #1 suction line Common cir #2 suction line Compressor #1 discharge cover Compressor #2 discharge cover (Internal) External 4-20 mA signal External 4-20 mA signal Entering chilled water nozzle Back of the control box Leaving condenser water nozzle Signal converter board Well brazed to the cir #1 suction line Well brazed to the cir #2 suction line Well brazed to the cir #1 liquid line Well brazed to the cir #1 liquid line Table 4c. Analog inputs — 4 compressor units Sensor Number S00 S01 S02 S03 S04 S06 S07 S08 S09 S10 S11 S12 S13 S14 S15 S16 S17 S18 S19 S20 S21 S22 S23 Description Evaporator Leaving Water Temperature Low Pressure Transducer Circuit #1 Low Pressure Transducer Circuit #2 High Pressure Transducer Circuit #1 High Pressure Transducer Circuit #2 Evaporator Water Temperature Reset (Field Supplied) Demand Limit (Field Supplied) Evaporator Entering Water Temperature Outside Air Temperature Percent Circuit Amps Circuit #1 & 3 Percent Circuit Amps Circuit #2 & 4 Suction Temperature Circuit #1 Suction Temperature Circuit #2 Liquid Line Temperature Circuit #1 Liquid Line Temperature Circuit #2 Low Pressure Transducer Circuit #3 High Pressure Transducer Circuit #3 Suction Temperature Circuit #3 Liquid Line Temperature Circuit #3 Low Pressure Transducer Circuit #4 High Pressure Transducer Circuit #4 Suction Temperature Circuit #4 Liquid Line Temperature Circuit #4 13 Sensor Locations – 3 Screw Compressor Unit Sensor Locations – 4 Screw Compressor Unit 14 IM 549 Digital Inputs Note: All digital inputs are 24 VAC. At 7.5 VAC to 24 VAC the digital input contacts are considered closed, and the signal level is high. Below 7.5 VAC, the contacts are considered open, and the signal level is low. Table 5a. Digital inputs — 2 compressor unit Number Description Lo Signal 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 Mechanical High Pressure Switch, Circuit #1 Liquid Presence Switch, Compressor #1 Motor Protect, Compressor #1 Oil Level Sensor, Compressor #1 (Reserved) System Switch (S1) Phase Voltage Monitor Pump Down Switch, Circuit #1 Mechanical High Pressure Switch, Circuit #2 Liquid Presence Switch, Compressor #2 Motor Protect, Compressor #2 Oil Level Sensor, Compressor #2 (Reserved) Unit Remote Stop Switch Evap Water Flow Switch Pump Down Switch, Circuit #2 Alarm Alarm Alarm Alarm Normal Normal Normal Normal Hi Signal Stop Alarm Normal Alarm Alarm Alarm Alarm Run Normal Pumpdown Normal Normal Normal Normal Stop Alarm Normal Run Normal Pumpdown Table 5b. Digital inputs — 3 compressor unit No. 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 IM 549 Description Mechanical High Pressure Switch, Cir #1 Liquid Presence Sensor Compr #1 Motor Prot Compr #1 Not Used Not Used System On-Off Switch Phase Volt Monitor Compr #1 PumpDown Switch Compr #1 Mechanical High Pressure Switch Cir #2 Liquid Presence Sensor Compr #2 Motor Prot Compr #2 Not Used Not Used Remote Start Stop Switch Evap Water Flow Switch PumpDown Switch Compr #2 Mechanical High Pressure Switch Cir #3 Liquid Presence Sensor Compr #3 Motor Prot Compr #3 Not Used Not Used Phase Volt Monitor Compr #2 Phase Volt Monitor Compr #3 PumpDown Switch Compr #3 Led Off Led On Alarm No Liquid Alarm — — Off Alarm Normal Alarm No Liquid Alarm — — Stop No Flow Normal Alarm No Liquid Alarm — — Alarm Alarm Alarm Normal Liquid Normal — — On Normal Pump DN Normal Liquid Normal — — Start Flow PumpDn Normal Liquid Normal — — Normal Normal Normal 15 Table 5c. Digital inputs — 4 compressor unit No. 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 0 1 2 3 4 5 6 7 Description Led Off Led On Mechanical High Pressure Switch, Cir #1 Liquid Presence Sensor Compr #1 Motor Prot Compr #1 Not Used Not Used System On-Off Switch Phase Volt Monitor Compr #1 PumpDown Switch Compr #1 Mechanical High Pressure Switch Cir #2 Liquid Presence Sensor Compr #2 Motor Prot Compr #2 Not Used Not Used Remote Start Stop Switch Evap Water Flow Switch PumpDown Switch Compr #2 Mechanical High Pressure Switch Cir #3 Liquid Presence Sensor Compr #3 Motor Prot Compr #3 Not Used Not Used Phase Volt Monitor Multi Point Not Used PumpDown Switch Compr #3 Mechanical High Pressure Switch Cir #4 Liquid Presence Sensor Compr #4 Motor Prot Compr #4 Not Used Not Used Not Used Not Used PumpDown Switch Compr #4 Alarm No Liquid Alarm — — Off Alarm Normal Alarm No Liquid Alarm — — Stop No Flow Normal Alarm No Liquid Alarm — — Alarm — Normal Alarm No Liquid Alarm — — — — Normal Normal Liquid Normal — — On Normal Pump DN Normal Liquid Normal — — Start Flow PumpDn Normal Liquid Normal — — Normal — PumpDn Normal Liquid Normal — — — — PumpDn Analog Outputs Table 6. Analog outputs No. 0 1 2 3 16 Description SpeedTrol, SpeedTrol, SpeedTrol, SpeedTrol, Circuit Circuit Circuit Circuit Signal Range #1 #2 #3 #4 0-10 0-10 0-10 0-10 VDC VDC VDC VDC IM 549 Digital Outputs Table 7a. Digital outputs — 2 compressor unit No. Description Off On 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 Alarm LED and Contact Chilled Water Pump EXV Serial Data 1 EXV Serial Data 2 MCR relay, Compr #1 Top Solenoid, Compr #1 Bottom Right Solenoid, Compr #1 Bottom Left Solenoid, Compr #1 MCR Relay, Compr #2 Top Solenoid, Compr #2 Bottom Right Solenoid, Compr #2 Bottom Left Solenoid, Compr #2 Condenser Fan #1, Circ #1 (M12) Condenser Fan #2, Circ #1 (M13) Condenser Fan #3, Circ #1 (M14) Condenser Fan #4, Circ #1 (M15) Condenser Fan #1, Circ #2 (M22) Condenser Fan #2, Circ #2 (M23) Condenser Fan #3, Circ #2 (M24) Condenser Fan #4, Circ #2 (M25) Liquid Solenoid Valve, Cir #1 Liquid Solenoid Valve, Cir #2 (Spare) (Spare) (Programmable) Stop (Programmable) Run Stop Hold Hold Hold Stop Hold Hold Hold Off Off Off Off Off Off Off Off Close Close Run Load Load Load Run Load Unload Load On On On On On On On On Open Open Table 7b. Digital outputs — 3 compressor unit Table 7c. Digital outputs — 4 compressor unit Relay Description Relay 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 Alarm Circuit Chilled Water Pump Relay EXV Control EXV Control Compr #1 Contactor Compr #1 Top Solenoid Valve Compr #1 Bottom Right Solenoid Valve (feed) Compr #1 Bottom Left Solenoid Valve (vent) Compr #2 Contactor Compr #2 Top Solenoid Valve (feed) Compr #2 Bottom Right Solenoid Valve (feed) Compr #2 Bottom Left Solenoid Valve (vent) Condenser Fan Contactor M-12 Condenser Fan Contactor M-13 Condenser Fan Contactor M-14 Condenser Fan Contactor M-15 Condenser Fan Contactor M-22 Condenser Fan Contactor M-23 Condenser Fan Contactor M-24 Condenser Fan Contactor M-25 Compr #3 Contactor Compr #3 Top Solenoid Valve (feed) Compr #3 Bottom Right Solenoid Valve (feed) Compr #3 Bottom Left Solenoid Valve (vent) Condenser Fan Contactor M-32 Condenser Fan Contactor M-33 Condenser Fan Contactor M-34 Condenser Fan Contactor M-35 Hot Gas Bypass - SV5 Hot Gas Bypass - SV6 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 IM 549 Description Alarm Circuit Chilled Water Pump Relay EXV Control EXV Control Compr #1 Contactor Compr #1 Top Solenoid Valve Compr #1 Bottom Right Solenoid Valve (feed) Compr #1 Bottom Left Solenoid Valve (vent) Compr #2 Contactor Compr #2 Top Solenoid Valve (feed) Compr #2 Bottom Right Solenoid Valve (feed) Compr #2 Bottom Left Solenoid Valve (vent) Condenser Fan Contactor M-12 Condenser Fan Contactor M-13 Condenser Fan Contactor M-14 Condenser Fan Contactor M-15 Condenser Fan Contactor M-22 Condenser Fan Contactor M-23 Condenser Fan Contactor M-24 Condenser Fan Contactor M-25 Compr #3 Contactor Compr #3 Top Solenoid Valve (feed) Compr #3 Bottom Right Solenoid Valve (feed) Compr #3 Bottom Left Solenoid Valve (vent) Condenser Fan Contactor M-32 Condenser Fan Contactor M-33 Condenser Fan Contactor M-34 Condenser Fan Contactor M-35 Hot Gas Bypass — SV5 Hot Gas Bypass — SV6 Not Used Compr #4 Contactor Compr #4 Top Solenoid Valve (feed) Compr #4 Bottom Right Solenoid Valve (feed) Compr #4 Bottom Left Solenoid Valve (vent) Condenser Fan Contactor M-42 Condenser Fan Contactor M-42 Condenser Fan Contactor M-42 Condenser Fan Contactor M-42 17 Installation Controller Calibration The control software is installed and tested by the factory prior to shipping therefore no periodic calibration of the controller is required. All control and safety set points will be checked and adjusted if necessary by the McQuayService start-up technician prior to starting the unit. The MicroTech controller contains default set points which will be appropriate for most common installations. Field Wiring Analog sensors and transducers Power wiring All sensors and transducers required for normal chiller operation are installed and wired by the factory. Any optional analog signals provided by the installing contractor require twisted, shielded pair wire (Belden #8760 or equal). 115VAC power for the control transformer is derived from the 3-phase power connection provided by the electrical contractor. A separate disconnect for the cooler heating tape and control circuit transformer may be supplied as options on some installations. Wiring for these circuits is to be provided by the installing contractor and should conform to the National Electrical Code and all applicable local building codes. Digital input signals Remote contacts for all digital inputs such as the chilled water flow switch and the remote start/stop switch must be dry contacts suitable for the 24 VAC control signals produced by the screw chiller control panel. Digital outputs Devices wired to the digital outputs typically be an optional Chilled Water Pump control relay or an Alarm Annunciator. The MicroTech output device is a normally open solid state relay with an on board, replaceable 5 amp fuse. The model 250 controller activates a solid state relay by sending a “trigger” signal to the output board via the attached ribbon cable. The relay responds to the trigger by lowering it’s resistance which allows current to flow through its “contacts”. When the controller removes the trigger signal, the relay’s resistance becomes very high, causing the current flow to stop. The status of all outputs are shown by individual red LEDs for ease of determining output status. Interlock wiring All interlock wiring to field devices such as flow switches and pump starters is provided by the installing contractor. Refer to the Field Wiring Drawing as well as the unit wiring schematics and typical application drawings at the end of this manual for details. External alarm circuit The MicroTech panel can activate an external alarm circuit when an alarm or pre-alarm condition is detected. A 24VAC voltage source is available at field wiring terminal #107 to power an external alarm device such as a bell, light or relay. An alarm annunciator rated for a maximum load of 1.8 Amps at 24VAC is to be provided and wired by the installing contractor. The normal and alarm states for the 24VAC alarm signal are programmable by the operator. Available settings are: Pre-alarm annunciation: Close-or-Open-or-Blink Alarm annunciation: Close-or-Open 18 Power supplies There are several internal power supplies used by the controller and its associated circuitry. The regulated 5 VDC power on terminal #42 is used to support the analog inputs on the ADI Board and should not be used to operate any external devices. An unregulated 12 VDC power supply is available on field wiring terminal #56 and an unregulated 24 VAC supply is provided at terminal #81. Both of these may be used for powering external devices such as low current relays and lights. Demand limit and chilled water reset signals Separate 4-20 milliamp signals for remote chilled water reset and demand limit can be provided by the customer and should be connected to the appropriate terminals on the field wiring strip inside the control cabinet. The optional demand limit and chilled water reset signals are 4 to 20 milliamp DC signals. The resistive load used to condition the milliamp input signals is a 249 ohm resistor factory mounted on the ADI Board. Communication ports Communication port “A” is provided on the MicroTech controller for connection to an IBM compatible computer for local or remote system monitoring (Belden 8762 or equivalent). The network uses the RS232 communication standard with a maximum cable length of 50 feet. All communication network wiring utilizes low voltage shielded twisted pair cable. See the Personal Computer Specification section of this manual for specific hardware requirements. Communication port “B” is used to link the unit controller into a MicroTech network using the RS-485 communication standard. Refer to the field wiring drawing in this manual for details. IM 549 Modem Kit Telephone line for remote modem access An optional modem kit may be installed for remote monitoring of the chiller from an off-site PC running McQuay’s Monitor software. The kit comes complete with modem, wiring harness and installation instructions. Remote monitoring of the MicroTech controller requires a dedicated telephone line supplied by the equipment owner. The McQuay Monitor software package used to establish a remote connection to the modem kit must be purchased separately. A voice quality, direct dial telephone line is required if remote access and monitoring of the unit controller is desired. The phone line should be terminated with a standard RJ-11 modular phone plug. Unit Sequence of Operation The following sequence of operation is typical for McQuay ALS air cooled and PFS water cooled chillers. The sequence may vary depending on various options which may be installed on the chiller. Off Conditions With power supplied to the unit, 115 VAC power is applied through the control fuse F1 to the compressor crankcase heaters, the compressor motor protector circuits, the primary of the 24V control circuit transformer and optionally, the evaporator heater (HTR5). The 24V transformer provides power to the MicroTech controller and related components. With 24V power applied, the controller will check the position of the front panel System Switch (S1). If the switch is in the “stop” position the chiller will remain off and the display will indicate the operating mode to be OFF:SystemSw. The controller will then check the PumpDown Switches. If any switch is in the “stop” position, that circuit’s operating mode will be displayed as OFF:RemoteComm if this operating mode is in effect. If an alarm condition exists which prevents normal operation of both refrigerant circuits, the chiller will be disabled and the display will indicate OFF:AllCompAlarm. The MicroTech controller allows the operator to manually set the chiller to an off mode via the keypad. The display indicates this operating mode with the message OFF:ManualMode. Assuming none of the above “Off” conditions are true, the controller will examine the internal time schedule to determine if the chiller should start. The operating mode will be OFF:TimeClock if the time schedule indicates an “off” time period. Start-up If none of the above “Off” conditions are true, the MicroTech controller will initiate a start sequence and energize the chilled water pump output relay. The display will indicate Starting as the operating mode. The chiller will remain in the Waiting For Flow mode until the field installed flow switch indicates the presence of chilled water flow. If flow is not proven within 30 seconds, the alarm output will be activated and the chiller will continue to wait for proof of chilled water flow. When chilled water flow is re-established, the alarm will be automatically cleared. Waiting for Load Once flow is established the controller will sample the chilled water temperature and compare it against the Leaving Chilled Water Set point, the Control Band and the Load Delay which have been programmed into the controller’s memory. If the leaving chilled water temperature is above the Leaving Chilled Water Set point plus + the adjustable Control Band plus the Start-up Delta Temperature Set point, the controller will select the refrigerant circuit with the lowest number of starts as the lead circuit and initiate the compressor start sequence. Start Requested In the Start Requested Mode, the electronic expansion valve is assumed to be fully closed. The MicroTech controller will read the evaporator pressure to ensure at least 4 psi of refrigerant pressure is present. If the evaporator pressure is less than 4 psi the compressor will not be enabled and the display will read “NoStart-LoEvap”. Prepurge In order to purge the compressor of any liquid refrigerant that may be present, the lead compressor is operated at 50% capacity while the electronic expansion valve is held fully closed. The refrigerant circuit will continue to run in this mode until either the evaporator refrigerant pressure drops IM 549 to less than 40 psi or 45 seconds has elapsed. If the evaporator pressure does not drop to 40 psi within the 45 seconds, the compressor will stop and the display will read “Failed Prepurge”. The alarm output will be activated. 19 Opened EXV With the evaporator pressure less than 40 psi and the compressor still running, the electronic expansion valve will be driven open to 200 steps. If the evaporator pressure rises above the freeze stat set point, the chiller will advance to Cool Staging Mode. If the circuit is in Cool Staging Mode and after 20 seconds, the evaporator pressure remains below the freeze state set point but is greater than 2 psi, the controller will transition to Low Ambient Start Mode. Low Ambient Start If the difference between the freeze stat set point and the evaporator refrigerant pressure is greater than 12 psi, the low ambient start timer will be set to 180 seconds. The compressor will continue to run for 180 seconds from the moment the expansion valve is opened in an attempt to build up the evaporator pressure. If the difference between the freeze stat set point and the evaporator refrigerant pressure is greater than 12 psi, the following calculation will be used to set the low ambient start timer: Low Ambient Timer = 360 - (Pressure Difference x 15) If the calculated low ambient timer value is greater than 360, the compressor will be stopped, the alarm output will be activated and the display will indicate “FailLowAmbStart”. Cool Stage Circuit capacity at initial start will be 50%. Once the chiller has started, the MicroTech controller will add or subtract cooling capacity to maintain the chilled water set point. The current cooling stage will be displayed on the keypad/display. Automatic chiller staging may be overridden by selecting “Manual Cooling” as the operating mode and then choosing the desired cooling stage. Compressor Control Normal Compressor Staging Logic The Compressor Staging Logic uses an adjustable control band and interstage timers to determine the correct number of cooling stages to activate. A project-ahead temperature calculation provides stable operation. The total number of cooling stages for each circuit is dependent upon the “number of cooling stages” set point. Compressor Staging Sequence Four Compressors Available Staging Up Lead Lag 1 Stage Compressor Compressor 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 20 — 50% 75% 50% 75% 75% 75% 75% 75% 75% 75% 75% 100% 100% 100% 100% — 0% 0% 50% 50% 75% 50% 75% 75% 75% 75% 75% 75% 100% 100% 100% Staging Down Lag 2 Lag 3 Compressor Compressor — 0% 0% 0% 0% 0% 50% 50% 75% 50% 75% 75% 75% 75% 100% 100% — 0% 0% 0% 0% 0% 0% 0% 0% 50% 50% 75% 75% 75% 75% 100% Unit Capacity Lead Compressor 0.0% 12.5% 18.8% 25.0% 31.3% 37.5% 43.8% 50.0% 56.3% 62.5% 68.8% 75.0% 81.3% 87.5% 93.8% 100.0% 25% 50% 75% 50% 75% 50% 75% 50% 75% 75% 75% 75% 100% 100% 100% 100% Lag 1 Lag 2 Compressor Compressor 0% 0% 0% 50% 50% 50% 50% 50% 50% 75% 75% 75% 75% 100% 100% 100% 0% 0% 0% 0% 0% 50% 50% 50% 50% 50% 75% 75% 75% 75% 100% 100% Lag 3 Compressor Unit Capacity 0% 0% 0% 0% 0% 0% 0% 50% 50% 50% 50% 75% 75% 75% 75% 100% 6.3% 12.5% 18.8% 25.0% 31.3% 37.5% 43.8% 50.0% 56.3% 62.5% 68.8% 75.0% 81.3% 87.5% 93.8% 100.0% IM 549 Three Compressors Available Staging Up Lead Lag 1 Stage Compressor Compressor 1 2 3 4 5 6 7 8 9 10 11 12 — 50% 75% 50% 75% 75% 75% 75% 75% 100% 100% 100% Staging Down Lag 2 Lag 3 Compressor Compressor — 0% 0% 50% 50% 75% 50% 75% 75% 75% 100% 100% — 0% 0% 0% 0% 0% 50% 50% 75% 75% 75% 100% — 0% 0% 0% 0% 0% 0% 0% 0% 0% 0% 0% Unit Capacity Lead Compressor 0.0% 12.5% 18.8% 25.0% 31.3% 37.5% 43.8% 50.0% 56.3% 62.5% 68.8% 75.0% 25% 50% 75% 50% 75% 50% 75% 75% 75% 100% 100% 100% Unit Capacity Lead Compressor 0.0% 12.5% 18.8% 25.0% 31.3% 37.5% 43.8% 50.0% 25% 50% 75% 50% 75% 75% 100% 100% Unit Capacity Lead Compressor 0.0% 12.5% 18.8% 25.0% 25% 50% 75% 100% Lag 1 Lag 2 Compressor Compressor 0% 0% 0% 50% 50% 50% 50% 75% 75% 75% 100% 100% 0% 0% 0% 0% 0% 50% 50% 50% 75% 75% 75% 100% Lag 3 Compressor 0% 0% 0% 0% 0% 0% 0% 0% 0% 0% 0% 0% Unit Capacity 6.3% 12.5% 18.8% 25.0% 31.3% 37.5% 43.8% 50.0% 56.3% 62.5% 68.8% 75.0% Two Compressors Available Staging Up Lead Lag 1 Stage Compressor Compressor 1 2 3 4 5 6 7 8 — 50% 75% 50% 75% 75% 100% 100% Staging Down Lag 2 Lag 3 Compressor Compressor — 0% 0% 50% 50% 75% 75% 100% — 0% 0% 0% 0% 0% 0% 0% — 0% 0% 0% 0% 0% 0% 0% Lag 1 Lag 2 Compressor Compressor 0% 0% 0% 50% 50% 75% 75% 100% 0% 0% 0% 0% 0% 0% 0% 0% Lag 3 Compressor 0% 0% 0% 0% 0% 0% 0% 0% Unit Capacity 6.3% 12.5% 18.8% 25.0% 31.3% 37.5% 43.8% 50.0% One Compressor Available Staging Up Lead Lag 1 Stage Compressor Compressor 1 2 3 4 — 50% 75% 100% Staging Down Lag 2 Lag 3 Compressor Compressor — 0% 0% 0% — 0% 0% 0% — 0% 0% 0% Lag 1 Lag 2 Compressor Compressor 0% 0% 0% 0% 0% 0% 0% 0% Lag 3 Compressor 0% 0% 0% 0% Unit Capacity 6.3% 12.5% 18.8% 25.0% Project-Ahead Calculation The Project-Ahead Calculation provides protection against an overshoot condition when the chilled water temperature is outside the control band. During cooling mode, if the Chilled Water Temperature is above the control band and the rate of temperature reduction is so great that in 120 seconds the chilled water temperature will be below the control band, the controller will stage down. The Project-Ahead Calculation also moderates the controllers response to a rapid increase in leaving water temperature. Interstage Timer The minimum time delay between stage up commands is set by the interstage timer set point (default=210 sec). The interstage timer for stage down commands is 1⁄3 of the stage up timer. Anti-Cycle Timer Anti-cycle timers are used to protect the compressors from excessive starts and high motor winding temperature. The anti-cycle timers are 5 minutes stop-to-start and 15 minutes start-to-start. Compressor Heater Control Compressor Heater Control for PFS units is based on the suction line superheat. If the superheat reading drops below IM 549 3°F, the heater will be energized. The heater will be deenergized when the superheat rises above 8°F. 21 Lead-Lag of Refrigerant Circuits The following compressor control rules are enforced in the control software. ● The MicroTech controller will never turn on the lag compressor until the lead compressor is at 75% capacity or greater and additional cooling capacity is required. ● The MicroTech controller will not turn off the lag compressor until the lead compressor is running at 50% capacity, the lag compressor is running at 25% capacity and a reduction in cooling capacity is required. Automatic Lead-Lag The controller provides automatic lead-lag of refrigeration circuits based on compressor operating hours and the number of starts. The circuit with the fewest number of starts will be started first. If circuits are operating and a stage down is required, the circuit with the most operating hours will cycle off first. Manual Lead-Lag The operator may override automatic circuit selection by manually selecting the lead circuit via the keypad. When the set point equals “auto”, the lead compressor is selected by the MicroTech controller based upon which circuit has the least operating hours. Regardless of the mode selected, if the lead circuit cannot operate due to an alarm condition or if off on cycle timers, the controller will switch to the lag circuit. Electronic Expansion Valve Overview McQuay screw compressor chillers are supplied with Sporlan SE-series electronic expansion valves. The MicroTech controller generates valve positioning signals to maintain refrigerant circuit superheat to within 1.5°F of the superheat set point. Valve positioning signals are converted to actuator step pulses by the EXV board which in turn drive the valve’s 3-phase DC stepper motor open or closed as required. A control range of 0 steps (full closed) to 760 steps (full open) is available to provide precise control of the valve position. EXV Superheat Control The electronic expansion valve position will be adjusted to maintain the refrigerant circuit’s superheat set point. Superheat set points are based on refrigerant circuit capacity. For circuit capacity of 25% to 50%, the superheat set point will be 8.0°F. For circuit capacity of 75% to 100%, the superheat set point will be 10.0°F. When the chiller control panel is powered up, the expansion valve will be driven closed 800 steps. This ensures that the valve is fully closed prior to a call for cooling. When all refrigerant circuit safeties are satisfied, the controller will initiate a start sequence. When the start sequence reaches “open solenoid”, the expansion valve will be driven open to the First Open set point (default=200 steps). The current suction line temperature is compared against the Suction Line Temperature set point (evaporator temp plus superheat spt) to calculate superheat error (Err). The current suction line temperature is also compared with the previous reading to calculate delta superheat error (DErr). These two error values are used to determine the magnitude and direction of the expansion valve positioning signal. A new valve positioning signal is calculated every 10 seconds, however, the interval at which these signals are issued to the EXV board is dependent on the magnitude of the required positional change. If no change is required, the interval will be 60 seconds. Forced EXV Position Change With an increase in circuit capacity, the electronic expansion valve position will be opened by a fixed percentage of its current position. This change will not occur if the superheat is less than 4°F below the superheat set point. With a decrease in circuit capacity, the electronic expansion valve position will be closed by a fixed percentage of its current position. Table 8b. Table 8a. 22 From When Staging Up To Open 25% 50% 75% 50% 75% 100% 65% 50% 25% From When Staging Down To Close 100% 75% 50% 75% 50% 25% 18% 40% 60% IM 549 EXV Evaporator Pressure Control The electronic expansion valve control will maintain a constant superheat for suction line temperature up to 60°F. For suction line temperatures greater than 61°F, the expansion valve control logic will maintain a constant evaporator temperature to avoid overloading the compressor motor. The control point will be the Evap Temp set point (default=50°F) and the control method will be the standard MicroTech Step and Wait algorithm. When the suction line temperature drops below 57°F, the MicroTech logic will resume normal superheat control. Chilled Water Reset Options Chilled Water Reset (Remote 4-20mA) The controller resets the chilled water set point based on an external 4 to 20mA signal. At 4 mA or less, no reset will occur. At 20mA, the chilled water set point will be reset by an amount equal to the value stored in the Maximum Reset set point. The reset schedule is linear and may be calculated using Figure 12. Figure 12. Percent of maximum reset 100 80 60 40 20 0 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 External 0-10mA signal Ice Mode The MicroTech controller has dual chilled water set points when ice mode is selected. With an external reset signal of 4mA or less, the chilled water reset will be zero. If the external reset signal is greater than 4mA, maximum reset will be in effect. For installations requiring operation in ice mode, the following set points should be adjusted to accommodate the reduced system temperature and pressures. Table 9. Set Point Monitors Default Ice Mode FreezeStat Low Evap Pressure 54 psig A pressure value equivalent to the leaving solution temperature minus 10°F FreezeH20 Leaving Solution 36°F A temperature value equal to the leaving solution temperature minus 4°F StpPumpDn Final Pumpdown 34 psig A pressure valve equal to the FreezeStat set point minus 10 psi Network Reset The reset mode can be set to “network” if chilled water reset via communications network is desired. The chiller controller IM 549 receives a signal from the network master panel in the range of 0% to 100% of maximum reset. 23 Return Water Reset When return water is selected as the reset mode, the MicroTech controller will adjust the leaving chilled water set point to maintain a constant return water temperature equal to the return water set point. The return water temperature is sampled every 5 minutes and a proportional correction is made to the leaving chilled water set point. The corrected leaving water set point is never set to a value greater than the return water set point and is never set to a value less than the actual leaving chilled water set point. Remote Demand Limit The controller will limit the total number of stages based on an external 4 to 20mA signal regardless of the amount of cooling actually required. A 4mA or less signal will enable all stages while a 20mA signal will allow only 1 stage to operate. The effect of the reset signal may be calculated by using Figure 13. Network Demand Limit Unit demand limit via network communication may be selected if desired. The chiller controller receives a demand limit signal from the network master panel in the range of 0% to 100% with 0 equaling no limit. Soft Loading The soft loading feature limits the number of cooling stages which may be energized by the controller to prevent unnecessary electrical demand and possible over-shoot of the desired leaving chilled water temperature. Soft loading is typically used during morning start-up. When the controller enters the “Cool Staging” mode of operation, the controller will start a count down timer to indicate how long the unit has been in the cool staging mode. The maximum number of cooling stages will be limited to the soft load set point until the soft load count down timer equals zero. Max Pull Down The controller can limit the rate at which the chilled water loop temperature is reduced. Whenever the rate of tempera- ture decrease exceeds the maximum pull down set point, no additional cooling stages will be activated. Condenser Fan Control Condenser Fan Staging The first condenser fan staging will be started in conjunction with the first compressor to provide initial head pressure control. The MicroTech controller continuously monitors the lift pressure referenced to several head pressure control set points and will adjust the number of operating condenser fans as required to maintain proper head pressure. For PFS water cooled units, the condenser pump will be started in conjunction with the first compressor to provide head pressure control. Head Pressure Control (Air Cooled Units Only) For each circuit, the first stage of condenser fans will be wired in parallel with the compressor output so that they are energized with the compressor. For chillers with optional SpeedTrol, the first condenser fan stage will receive a control signal from the AOX board which in turn modulates the Johnson Controls S66DC-1 to provide variable speed fan operation. Each circuit has 3 additional digital outputs available for refrigerant head pressure control. Each output will energize an additional bank of condenser fans with each bank consisting of 1 or 2 fans depending on the size of the unit. Each output energizes additional heat rejection due to increased air flow across the air cooled condenser regard- 24 less of the number of fans. If the outdoor ambient temperature is greater than 60°F when the unit is started, one additional condenser fan stage will be energized. If the outdoor ambient temperature is greater than 80°F, two additional fan stages will be energized. ALS unit EERs are maximized by not allowing the last condenser fan stage to operate when the unit capacity is 25% and the condenser pressure is below 200 psi. The last fan stage will operate if the condenser pressure is above 220 psi at 25% unit capacity. IM 549 Lift Pressure Calculation The minimum acceptable lift pressure is determined by the expansion valve. At low tonnage capacities, a minimum lift pressure of approximately 60 psid must be maintained. At higher tonnage capacities, a higher lift pressure must be maintained to provide proper refrigerant flow through the expansion valve. Refer to the following table for the lift pressure values maintained at various unit capacities. Individual head pressure set points are provided at 25%, 50%, and 100% circuit capacity to optimize chiller operation. For operation at 75% capacity and greater with outdoor air temperatures less than 60°F, the minimum lift will automatically be reset downward. The maximum available reset at 100% capacity is 40 psid while the maximum reset at 75% capacity is 20 psid. Table 10. Capacity Set Point Adjustment Range 25% 50% 75% 100% 60 psig 70 psig 105 psig 140 psig 60-100 70-100 Fixed 100-140 Figure 13. Min list SPT at 100% Area of reset based on OAT AT tO in lif ta 105 M Minimum lift (psig) >= 60 ° 140 Min lift A at O T> = 0° Low limit for min lift SPT at 100% 69 60 25% 50% 75% 100% Compressor capacity Lift Pressure Dead Band The MicroTech controller establishes a dead band above the minimum lift pressure that varies with circuit capacity. If the lift pressure is within the dead band, no fan staging will occur. Condenser fan staging will occur as follows for lift pressures above or below the dead band. Table 11a. Unit Capacity Stage 0 Stage 1 100% 75% 50% 25% 120 120 60 50 100 70 50 30 Unit Capacity Stage 0 Stage 1 100% 75% 50% 25% 40 40 70 80 40 40 30 30 Deadband Table – No SpeedTrol Stage 2 Stage 3 60 50 30 20 40 30 20 10 Stage 4 Stage 5 Stage 6 30 25 15 10 25 20 15 10 20 20 15 10 Stage 4 Stage 5 Stage 6 30 25 15 10 25 20 15 10 20 20 15 10 Table 11b. IM 549 Deadband Table – With SpeedTrol Stage 2 Stage 3 40 40 30 20 40 30 20 10 25 Condenser Fan Stage Up Every four seconds, the controller records the difference between the maximum condenser pressure (as defined by the minimum lift plus the dead band) and the actual condenser refrigerant pressure. This value is added to the previously recorded values and when the accumulated total is equal to or greater than the stage up set point, the controller starts an additional fan stage. The accumulated total is set to zero whenever a fan stage change occurs or the condenser pressure falls inside the dead band. Fan stages 5 or 6 will not be enabled unless the circuit capacity is greater than 50%. High Pressure Stage Up The controller logic will bring on multiple condenser fan stages if a rapid rise in pressure is detected. Condenser Fan Stage Down Every four seconds, the controller records the difference between the minimum condenser pressure and the actual condenser refrigerant pressure. This value is added to the previously recorded values and when the accumulated total is equal to or greater than the stage down set point, the controller decrements a fan stage. The accumulated total is set to zero whenever a fan stage change occurs or the condenser pressure rises inside the dead band. Fan stages 5 or 6 will automatically be disabled whenever the circuit capacity falls to 50% or less. SpeedTrol Logic When the SpeedTrol option is installed, the MicroTech controller will generate an analog signal via the AOX board to directly control the S66DC-1 variable speed fan motor control. The control signal is proportional to the condenser pressure’s relative position within the lift pressure dead band. Minimum and maximum fan speed is defined by the minimum and maximum lift pressure set points so that when the condenser pressure is below the dead band, the fan speed will be set to 0% and when the condenser pressure is above the dead band, the fan motor speed will be set to 100%. Figure 14. 100% SpeedTrol motor voltage 90% 80% 70% 60% 50% 40% 30% 20% 10% 0% 10 9 8 7 6 5 4 3 2 1 0 Input voltage from AOX board Pumpdown Automatic Pumpdown As the system chilled water requirements diminish, the compressors will be unloaded. As the system load continues to drop, the electronic expansion valve will be driven to 0 steps, (closed) and the refrigerant circuit will go through a PumpDown sequence. As the evaporator pressure falls below the StopPumpDownPres set point while pumping down, 26 the compressors and condenser fans will stop. If the evaporator pressure is greater than the StopPumpDownPres set point after 180 seconds have elapsed, the compressor will stop and the display will read “Can’t Pump Down”. The alarm output will be activated. IM 549 Manual Pumpdown When the compressor is running and the circuit pumpdown switch is moved from the Auto position to the Stop position, the circuit will pumpdown and stop when the evaporator pressure falls below the “StopPumpdownPressure” set point. When the compressor is not running and the circuit pumpdown switch is moved from the Auto position to the Stop position, the controller will initiate a pumpdown only if the evaporator pressure is above the “Begin Pumpdown Pressure” set point. The compressor will stop when the evaporator pressure falls below the “Stop Pumpdown Pressure” set point. An additional pumpdown sequence can be performed by moving the pumpdown switch to the Auto position for approximately 3 seconds and then back to the Stop position. If the evaporator pressure is above the “Begin Pumpdown Pressure” set point, the controller will initiate a pumpdown sequence and the compressor will stop when the evaporator pressure falls below the “StopPumpdownPressure” set point. Service Pumpdown The normal pumpdown sequence will stop when the evaporator pressure equals the Stop Pumpdown set point pressure. A control set point called FullPumpDown has been provided which will allow an extended pumpdown for service purposes. The default value for the FullPumpDown set point is “No”. By changing this setting to “Yes”, the circuit will attempt to pump down to 2 psi during the next pumpdown cycle. If 2 psi cannot be obtained, the compressor will stop after 300 seconds have elapsed. The set point will be set to “No” automatically at the end of the cycle. Note: All pumpdown modes are disabled if the system switch (S1) is in the Stop position. Note: Compressor capacity during a pumpdown sequence will be 50%. Safety Systems System Alarms Alarm conditions which are common to both refrigerant circuits are considered to be system alarms. On a system alarm, the MicroTech controller will shut down both compressors and energize the alarm output. Loss of Chw flow On a loss of chilled water flow for three consecutive seconds while the chiller is in cooling mode, all operating refrigerant circuits will pump down and stop. The display will read “Loss of ChW Flow”. When chilled water flow resumes, the chiller will initiate a normal start sequence. cates that the incoming power is back within acceptable limits, normal chiller operation will resume. No 5VDC @AI#5 The controller continuously monitors the output of both internal 5VDC power supplies and calculates their ratio. If the microprocessor is not receiving an acceptable volts ratio signal, the unit will be shut down. The voltage present at analog input #5 must be between 4.15 and 4.94 VDC. Chilled water freeze protect Bad phase/voltage If the leaving chilled water temperature falls below the adjustable freeze H2O set point, the unit will be shut down. The factory mounted voltage protection device will signal the MicroTech controller if the incoming 3-phase power is not within acceptable limits. The controller will immediately shut the chiller down. When the voltage protection device indi- Bad leaving chilled water sensor If the MicroTech controller detects an open or shorted leaving water sensor, the chiller will be shut down. Circuit Alarms Alarm conditions which are unique to each refrigerant circuit are considered to be circuit alarms. On a circuit alarm, the MicroTech controller will shut down the affected circuit’s compressor and energize the alarm output. High condenser pressure If the condenser pressure as sensed by the pressure transducer exceeds the high condenser pressure set point (default=380 psi), the circuit will be shut down until the alarm is manually reset. Mechanical high pressure Closure of the HP1 or HP2 relay contacts indicates an abnormally high compressor discharge pressure. The latching mechanical high pressure switch must be reset before the MicroTech alarm can be cleared. The mechanical high pressure switches should be set to trip at the following pressures. ALS Units . . . 400 psi PFS Units . . . 380 psi IM 549 High condenser pressure stage down If the condenser pressure rises to within 20 psi of the condenser high pressure set point, the controller will automatically reduce the refrigerant circuit’s capacity by one cooling stage every 10 seconds until the condenser pressure falls below the 20 psi threshold. (HiCondPre-20) If two high pressure stage downs occur within a 60 minute period, the normal interstage timer will be extended to 15 minutes to inhibit any stage up requests. Normal chiller staging will resume once this 15 minute timer expires. 27 High condenser pressure stage hold If the condenser pressure rises to within 30 psi of the condenser high pressure set point, the controller will hold the circuit at its current capacity. Normal chiller operation will resume once the condenser pressure drops below the high pressure stage hold threshold. Once the time delay is satisfied, the controller will stage down once every 20 seconds. If the controller stages down to cooling stage 0, the circuit will pump down and the compressor will stop. The circuit will restart automatically when the anti cycle timer expires. Failed pre-purge No liquid start If liquid refrigerant is not present at the compressor’s injection port within 20 seconds of a start request, the circuit will be shut down and the fault will be recorded. The circuit will automatically attempt to re-start after the cycle timer expires. If a no liquid start is recorded during the second start attempt, the circuit is shut down and the alarm output is energized. No additional starts will be attempted until the alarm is manually cleared. The start sequence will be aborted if the compressor cannot pre-purge the evaporator. Failed EXV or low refrigerant charge If the pre-purge is successful but the evaporator pressure does not rise after the electronic expansion valve is commanded to open, the circuit will be shut down. Failed low ambient start The circuit will be shut down if the controller records an unsuccessful low ambient start. No liquid run The refrigerant circuit will be shut down if liquid injection is lost during normal chiller operation. One automatic re-start will occur after the cycle timer expires. If another no liquid run fault is recorded after the re-start, the circuit will be shut down and the alarm output will be energized. Can’t pump down Can’t start-low evaporator pressure A pumpdown elapse timer (180 seconds) is started whenever the controller initiates a pumpdown sequence. If the circuit is still attempting to pump down when the timer expires, the compressor is stopped and the alarm output is activated. The display reads “Can’t Pump Down”. If the evaporator pressure is less than 4 psi when a compressor start is requested, the start will be aborted. Bad evaporator pressure sensor Low evaporator pressure A shorted or open evaporator pressure sensor will shut down the refrigerant circuit and activate the alarm output. A low evaporator pressure alarm will occur if the refrigerant pressure drops below the low pressure cutout set point (default=2 psi). Bad condenser pressure sensor Freeze protect stage down and freeze stat protect A shorted or open condenser pressure sensor will shut down the refrigerant circuit and activate the alarm output. The controller records the amount of time the evaporator refrigerant pressure is below the freeze stat set point (default=54 psi). The magnitude of the error will determine the time delay before a circuit stage down or alarm shutdown occurs. Wait flooded Table 12. Liquid presence sensor detected liquid in the compressor. xxx indicates time in minutes before unit will start after liquid clears from the compressor. 28 Error S.D. Delay Alarm Delay 2 psi 4 psi 6 psi 8 psi 10 psi 12 psi 14 psi 17 psi 100 seconds 87 seconds 74 seconds 60 seconds 48 seconds 35 seconds 22 seconds 0 seconds 160* 140 100 100 80 40 40 0 Suction superheat is less than 3°F and compressor will not start. Wail flooded xxx IM 549 MicroTech Controller Test Procedures ! CAUTION Service test mode should only be used by McQuayService personnel or other factory trained technicians. The following test procedures will disable all normal chiller controls and safeties. All compressors MUST be disabled by opening circuit breakers or by disconnecting the 3-phase power before beginning tests. Failure to do so can result in severe compressor damage. Service Test (Digital Outputs) Select control mode, menu 13 and set the chiller’s control mode to Service Testing. Select menu 22 and with the Prev or Next item keys, select the digital output you wish to test. Enter the service password when prompted by the display. Pressing the Inc key will turn the selected output on, pressing the Decr key will turn it off. All outputs except 1, 2, 4 and 8 will remain in their last commanded state until the Service Testing mode is turned off. Manually operating outputs 1 and 2 will drive the electronic expansion valve open or closed. Compressor MCR outputs 4 and 8 will only remain in the on state for 15 seconds. Exit the Service Testing mode by selecting the desired chiller operating mode from menu 13. Service test (Digital Inputs) Select control mode, menu 13 and set the chiller’s control mode to Service Testing. Select menu 22 and with the Prev or Next item keys, select test #16, DH1. The current state of the first 8 digital inputs (0-7) will be represented on the keypad/display as a row of ones or zeroes where 1 equals “on” and 0 equals “off”. By manipulating field wired devices (system switch, motor project, etc.) and watching the keypad/display, the status of the first eight digital inputs can be verified. Press the Next item key to select test #17, DH2. The current state of the second 8 digital inputs (8-15) will be represented on the keypad/display as a row of ones or zeros where 1 equals “on” and 0 equals “off”. By manipulating field wired devices (flow switch, remote stop switch, etc.) and watching the keypad/display, the status of the second eight digital inputs can be verified. Exit the Service Testing mode by selecting the desired chiller operating mode from menu 13. Keypad/Display Overview The information stored in the MicroTech controller can be accessed through the keypad using a tree-like structure. This tree structure is divided into Categories, Menus and Menu Items. There are three categories which make up the tree structure: STATUS, CONTROL, and ALARM. Each category is divided into Menus and each menu into Menu Items. The three categories are described below. Status Category Menus and menu items in this category provide information on the MicroTech operating conditions and the chiller operating conditions. The entries under each menu item in this category provide information only and are not changeable through the MicroTech keypad. Control Category Menus and menu items in this category provide for the input of all the unit control parameters. These include cooling control, compressor control and IM 549 condenser fan control parameters as well as time schedules and alarm limits. The entries under these menu items are changeable through the MicroTech keypad. 29 Alarm Category Menus and menu items in this category provide information regarding current and previous alarm conditions. Display Format The information stored in the MicroTech controller tree structure can be viewed (one menu and menu character LCD display. The current MENU is shown on the top line and the current MENU ITEM is shown on the bottom line of the display. The operator can select either English or metric engineering units. Once the desired engineering units have been selected, momentarily remove and restore power to the MicroTech controller to complete the change. English Units: Temperature = Pressure = Metric Units: Temperature = Pressure = °F Psi Psig Psid (Fahrenheit) (Pound per sq. inch) °C Kpa Kpag Kpda (Centigrade) (Kilo Pascals) MicroTech Component Test Procedures & ALS Units Status LED diagnostics The MCB status LED indications can aid in controller diagnostics. If the status LEDs do not operate normally as described in the “Component Data” section of this handout (see Tables 1 & 2), there is a problem with the MCB. Following are troubleshooting procedures for the various symptoms. Red LED remains on If the red LED remains on after the 5-second self-test period, it is likely that the MCB is defective. However, this can also occur in some instances if there is a power supply problem. Refer to “Troubleshooting Power Problems” below. Red and green LEDs off If the red and green LEDs do not turn on after power is applied to the controller, there is likely a defective component or a problem in the controller’s power distribution circuits. Refer to “Troubleshooting Power Problems” below. Troubleshooting Power Problems The MCB status receives 18 Vac, center-tapped power from a transformer. It then distributes both 5 Vdc and 13 Vdc power to various MicroTech components. A problem that exists in any of these components can affect the MCB and thus the entire control system. Power problems can be caused by an external short, which can blow a fuse, or a defective component, which can either blow a fuse or create an excessive load on the power supply. An excessive load can lower the power supply voltages to unacceptable levels. Use the following procedure to isolate the problem. Note: This procedure may require two or three spare MCB fuses. 1. Verify that circuit breaker CB1 is closed. 2. Remove the MCB Power In connector and check for 9 Vac between the terminals on the plug corresponding to terminals 2 and 3 on the board (Figure 2). Then check for 9 Vac between the terminals on the plug corresponding to terminals 1 and 3 on the board. (Readings of 9-12 Vac are acceptable.) If 9 Vac is present between both sets of terminals, go to step 3. If 9 Vac is not present between both sets of terminals, check both transformers and all wiring between the 115 Vac source and the Power In plug. 3. Remove power from the controller by opening circuit breaker CB1. Check the MCB power supply input fuses (F1 and F2) with an ohmmeter. See Figure 3. A good fuse will have negligible resistance through it (less than 2 ohms). If either or both fuses are blown, replace them. Go to step 4. If the fuses are intact, the MCB is defective. 30 4. Reconnect the Power In connector and disconnect all other connectors on the MCB. Cycle power to the controller (close and then open CB1) and check the power fuses. If both fuses are intact, go to step 5. 5. If either fuse blows, the MCB is defective. Reconnect the keypad/display ribbon cable (if equipped with keypad/ display door). Cycle power to the controller and check the power fuses. If both fuses are intact, go to step 6. If either fuse blows, check the keypad/display and the connecting ribbon cable for shorts. Either one may be defective. 6. Reconnect the analog input ribbon cable. Cycle power to the controller and check the power fuses. If both fuses are intact, go to step 7. If either fuse blows, check the ADI board, the connecting ribbon cable, and the field wiring for shorts. Any of these may be defective. Try repeating this step after removing or swapping the ADI board. 7. Reconnect the digital input ribbon cable. Cycle power to the controller and check the power fuses. If both fuses are intact, go to step 8. If either fuse blows, check the ADI board, the connecting ribbon cable, and the field wiring for shorts. Any of these may be defective. 8. Reconnect the digital output ribbon cable to the MCB. Cycle power to the controller and check the power fuses. If both fuses are intact, go to step 9. If either fuse blows, check Output Board and the connecting ribbon cable. Either of these may be defective. IM 549 circuit breaker CB1 open, measure the resistance between field terminals “DC-GRD” and “13 Vdc.” It should steadily rise to a value greater than 5000 ohms (within approximately 30 seconds). If the resistance rises above 5000 ohms, go to step 13. If the resistance does not rise above 5000 ohms, the MCB is defective. 13. one at a time, reconnect the modem and each AOX-4 board (as applicable). Each time a component is reconnected, measure the resistance between field terminals “DC-GRD” and “13 Vdc.” It should steadily rise to a value greater than 5000 ohms. If the resistance rises above 5000 ohms, repeat this step until the modem and all AOX-4 boards (as applicable) have been checked out. If the problem persists, it is indeterminate. Obtain factory service. If the resistance does not rise above 5000 ohms, the modem or the AOX-4 board just connected is defective. (With the power plug disconnected, the resistance across an AOX-4 board’s “DC” and “G” terminals should not be less than 3 million ohms.) Figure 15. MCB power supply terminals Power fuses (Bussman GDC-T2A) Power in [18-24 VCT] AC AC GND GND 9. If there are any AOX-4 boards, reconnect the expansion bus ribbon cable to the MCB; otherwise, go to step 10. Cycle power to the controller and check the power fuses. If both fuses are intact, go to step 10. If either fuse blows, check the analog output expanion modules (if any), the connecting ribbon cables, and the field wiring for shorts. Any of these may be defective. 10. With circuit breaker CB1 open, measure the resistance between field terminals “DC-GRD” and “5 Vdc.” It should be greater than 20 ohms. If the resistance is greater than 20 ohms, go to step 11 if the controller is equipped with at least one AOX-4 board or a modem. Otherwise, the problem is indeterminate. Obtain factory service. If the resistance is less than 20 ohms, it is likely that the keypad/display, the Output Board, or an external (field supplied) load is excessively loading the MCB’s 5 Vdc power supply. Isolate the problem by taking resistance measurements on each of these devices with the wiring disconnected. The resistance across the power input terminals on the keypad/display (G and 5V) should be close to infinite. The resistance across the power input terminals on the Output Board (+ and -) should not be less than 3000 ohms. If the component resistances are proper, check the resistance of the field supplied loads (if any) and check the wiring and connections throughout the 5 Vdc power supply circuit. 11. Disconnect the connector plugs from the modem and the power plug from all AOX-4 boards (as applicable). With circuit breaker CB1 open, measure the resistance between field terminals “DC-GRD” and “13 Vdc.” It should be infinite. If the resistance is infinite, go to step 12. If the resistance is not infinite, a short exists somewhere in the 13 Vdc power supply wiring. 12. Reconnect the Aux/Out connector plug to the MCB. If there’s a modem, reconnect its AMP plug to port A. With Fuse F1 Fuse F2 AUX/OUT Troubleshooting Communications Problems If a communications problem occurs, check the following items: ● ● ● ● Check the port B voltages Check the port B fuses Check the network integrity Check the network addressing The best way to accomplish these checks is to perform the start-up procedures as specified in the “Network Commissioning” section of the appropriate IM manual. If these procedures have performed and the problem persists, obtain factory service. Troubleshooting the Keypad/Display Interface The Keypad/Display Interface is connected to the MCB via a ribbon cable and discrete wiring for the back light. The MCB provides operating voltages, control signal outputs for the display, and input conditioning for the keypad inputs. out. To check for the 5 Vdc on the IDC connector, pull back the plug about one-eighth of an inch and place the test leads against the exposed pins. If there is no voltage the MCB is probably defective. Display is hard to read Display is blank or garbled The clarity of the LCD display can be affected by ambient temperature. Typically, less contrast will result with cooler temperatures. If the display is difficult to read, adjust the contrast trim pot, which is located on the back of the keypad/ display assembly. If the MCB appears to be functioning properly and the display is completely blank or garbled, perform the following procedure: 1. Try cycling power to the controller by opening and then closing circuit breaker CB1. 2. Try adjusting the contrast trim pot, which is located on the back of the keypad/display assembly. If the contrast trim pot has no effect, it is likely that either the keypad/display or its ribbon cable is defective. 3. After removing power from the controller, check the ribbon cable and connections between the keypad/display and the MCB. Look for bent pins. Restore power after reconnecting the ribbon cable. Back light not lit The Keypad/Display Interfaces supplied with the MicroTech control panel is equipped with a back light. If the light does not come on, check for 5 Vdc at terminal 9 on the IDC connector on the KDI and for 5 Vdc on the field wiring terminal strip. Check for 5 Vdc on the IDC connector on the MCB aux/ IM 549 31 4. Try swapping a known good ribbon cable and keypad/ display. Swap these components separately to isolate the problem. Remove power from the controller before dis- connecting the suspect component, and restore power after connecting the replacement component. If the problem persists, it is likely that the MCB is defective. Troubleshooting Analog Inputs An analog input, such as a temperature sensor, is connected to the Analog Input terminal strip on the ADI board. The analog input is then conditioned by the ADI board. The conditioned input is transferred to the MCB via a ribbon cable. Analog input not read by the MCB If the MCB appears to be functioning properly and the analog input is not being read by the MCB, perform the following procedure: 1. Try cycling power to the controller by opening and then closing circuit breaker CB1. 2. Check the ribbon cable, power wiring connector, and the field wiring connections from the analog input device. Look for bent pins, cable on backwards, or miswires. Restore power after reconnecting all cables and wires. 3. If the problem persists, try swapping a known good ribbon cable, an ADI board, or analog input device. Swap these components separately to isolate the problem. Remove power from the controller before disconnecting the suspect component, and restore power after connecting the replacement component. If the problem persists, it is likely that the MCB is defective. Troubleshooting Digital Inputs A digital input device is connected to the Digital Input terminal strip on the Input Conditioning Module Terminal Board. 24 Vac, supplied by the CSC, is sent to the digital input device via a supply wire. When a contact in the digital device makes, a return signal is sent back to the Digital Input terminal strip. The signal is then conditioned by the Input Conditioning Module (ICM). The conditioned digital input is then sent to the MCB via a ribbon cable. Digital input not read by the MCB If the MCB appears to be functioning properly and the digital input is not being read by the MCB, perform the following procedure: 1. Try cycling power to the controller by opening and then closing circuit breaker CB1. 2. Check the ribbon cable, power wiring connector, and the field wiring connections from the digital input device. Look for bent pins, cable on backwards, or miswires. Restore power after reconnecting all cables and wires. 3. If the problem persists, try swapping a known good ribbon cable, an ADI board, or a digital input device. Swap these components separately to isolate the problem. Remove power from the controller before disconnecting the suspect component, and restore power after connecting the replacement component. If the problem persists, it is likely that the MCB is defective. Troubleshooting Analog Outputs Variable voltage or current control signals are sent to analog outputs by the MCB through the Analog Output Expansion Module (AOX-4) (This can be on the ALS units as the optional fan speed control). The MCB sends a voltage or current signal to the AOX-4 via a ribbon cable. Jumpers on the AOX4 determine what type of output will be sent to the analog output device. The analog output signals are sent from the AOX-4 by connecting a two-pin Phoenix connector to the Analog Output Ports on the AOX-4. Analog output device is not operating correctly If the MCB appears to be functioning properly and the analog output device is not operating correctly, perform the following procedure: 1. Try cycling power to the controller by opening and then closing circuit breaker CB1. 2. Check the ribbon cable(s), power wiring from the transformer to the AOX-4, field wiring connections from the 32 AOX-4 to the analog output device, and the power wiring from the external power supply to the output device. Look for bent pins, cable on backwards, or miswires. Restore power after reconnecting all cables and wires. Note: If the analog output signal supplied by the MCB is a voltage signal (0-5, 0-10 Vdc), the external power supply ground must be grounded to the MCB chassis ground. 3. If the problem persists, try swapping a known good AOX4, ribbon cable(s), analog output device, or external power supply. Swap these components separately to isolate the problem. Remove power from the controller and analog output device before disconnecting the suspect component, and restore power after connecting the replacement component. If the problem persists, it is likely that the MCB is defective. IM 549 Troubleshooting Output Boards Each output on the Output Board consists of a solid-state relay, a LED, 5-amp fuse, and an MOV (metal oxide varistor). Normally, when the MCB commands an output to energize, the solid-state relay contacts will close and the LED will glow. The contacts of each solid-state relay are in series with a 5-amp fuse. These fuses resemble small resistors and are located on the board adjacent to the relays they serve. The fuses are pressed into place. They can be removed with a needle nose pliers. The MOV, which is located on the underside of the output board, protects the solid-state relay from high transient voltages. MOVs are part of the output board and cannot be replaced. Following are troubleshooting procedures for various symptoms of output board problems. Note: It should be possible to determine whether a solidstate relay is defective by using these procedures. However, if you need more information on troubleshooting them, refer to “Troubleshooting Solid-State relays” below. Figure 16. Output board relay socket 1 Fuse 2 *250V~50/60 Hz *120V~50/60 Hz 3 Test resistor 330-680 Ohm 4 5 ! WARNING Electric shock hazard. Can cause severe injury or death. Even when power to the panel is off, solid-state relay socket terminals 1 and 2 on the output board could be connected to high voltage (see Figure 5). Avoid them. One LED out If one of the Output Board LEDs fails to illuminate when the MCB is commanding the associated output to energize, perform the following procedure: 1. Remove power from the controller by opening CB1. Swap the suspect relay with a known good relay. Try to choose a relay that will not affect unit operation. Restore power by closing CB1. If the LED does not light, go to step 2. If the LED lights, the suspect relay is defective. 2. Remove power from the controller. Check the ribbon cable and connections between the OB and the MCB. Look for bent pins. If the cable and connections are intact, go to step 3. 3. Remove the relay from the suspect socket. Install a 330680 ohm resistor between terminals 3 and 5 as shown in IM 549 Figure 5. Restore power by placing CB1 to the ON position. The LED should light regardless of the controller’s command. If the output LED illuminates, it is likely that the MCB is defective. If the output LED does not illuminate, the output board is defective. All LEDs out If the MCB is commanding at least two outputs to energize and none of the Output Board LEDs are lit, perform the following procedure: 1. Verify that 5 Vdc is present at the Output Board’s power terminals. If 5 Vdc is not present, go to step 2. If 5 Vdc is present, check the ribbon cable and connections between the output board and MCB. Look for bent pins. If the cable and connections are intact, the Output Board or the MCB is defective. 2. Remove power from the controller by placing CB1 to the OFF position. Disconnect at least one wire from the power input terminals of the Output Board. The resistance should not be less than 3000 ohms. If the resistance is greater than the acceptable value, go to step 3. If the resistance is less than the acceptable value, the Output Board is defective. LED lit, output not energized If the LED of a suspect is lit but the load connected to it is not energized, and everything is intact between the MCB and the coil side of the relay, perform the following procedure to isolate the problem: 1. Verify that 24 or 120 Vac power is present at the suspect output’s screw terminal on the Output Board. 2. Remove power from the controller by placing CB1. Swap the suspect relay with a known good relay. Try to choose a relay that will not affect unit operation. Restore power by closing CB1. If the output load energizes, the suspect relay is bad. Replace the relay. If the output load does not energize (when LED is lit again), check the load circuit wiring and components. Output energized, LED not lit If the LED of a suspect is not lit, but the load connected to it is energized, either the solid-state relay or the MOV is bad. The solid-state relay contacts and the MOV, which are in parallel, can both fail closed. Perform the following procedure to isolate the problem: 1. Remove power from the controller by opening CB1. Pull the solid-state relay from the suspect output’s socket. 2. Restore power by closing CB1. If the output load remains energized when there is no relay in the socket, the output’s MOV has failed and thus the Output Board must be replaced. If the output load de-energizes, the relay that was pulled is defective. Contact chatter Contact chatter is very rapid opening and closing of contacts. It is usually caused by low voltage at the electromechanical relay or contactor coil. If contact chatter is occurring on a relay or contactor connected to one of the Output Board 33 solid-state relays, it is also possible that a faulty connection exists on the power supply terminals of the Aux/Out plug connector on the MCB and the Output Board. In very rare instances, contact chatter can be caused by a faulty solidstate relay. Perform the following procedure to isolate the problem: 1. Verify that the voltage at the load’s power supply and at the solid-state relay contacts is adequate. 2. Remove power from the controller by opening CB1. Swap the suspect relay with a known good relay. Try to choose a relay that will not affect unit operation. Restore power by closing CB1. If the chatter does not stop, go to step 3. If the chatter stops, the suspect relay is defective. Replace the relay. 3. Remove power from the controller by opening CB1. Try to improve the connections in the Aux/Out plug insulation displacement terminals by pressing down on the wires with a small screwdriver. 4. Check all other wiring and connectors for bent pins or miswires. If the chatter does not stop, the electromechanical relay or contactor is probably defective. Troubleshooting Solid-State Relays As shown on the unit wiring diagrams, the solid-state relays on the Output Boards all have normally open “contacts.” Actually, these contacts do not exist as they do in electromechanical relay. Instead of using contacts to switch the load, the solid-state relay changes its resistance from low (closed), when it is energized, to high (open), when it is de-energized. (This high resistance is approximately 100K ohms.) Because the output circuit through the solid-state relay remains continuous regardless of whether the relay is energized, troubleshooting a solid-state relay with a voltmeter can be tricky. In a typical circuit, a power source is connected across a single relay output and a load (see Figure 17). In this circuit, a solid-state relay will behave like an electromechanical relay. If the relay is energized, the relay output will be hot. If the relay is de-energized, voltage cannot be measured at the relay output. The circuit shown in Figure 6 is similar to a typical circuit; the difference is that there is an open set of contacts, or a disconnection between the relay output and the load. In this circuit, a solid-state relay will not behave like an electromechanical relay. If the solid-state relay is energized, the relay output will be hot (as expected). However, if the solid-state relay is de-energized, the relay output will still appear to be hot. This is because the relay output and the voltmeter form a continuous circuit in which the relay’s resistance, though high, is insignificant compared to the voltmeter’s resistance. This means that nearly all the voltage is dropped across the voltmeter. Therefore, the voltmeter indicates that voltage is present. If a low wattage light bulb of the appropriate voltage is used instead of a voltmeter, the bulb’s low resistance will load the circuit enough to eliminate the false voltage indication. In this situation, an incandescent test lamp is a better tool than a voltmeter. Figure 17b. Testing a typical relay circuit with a disconnection Figure 17a. Testing a typical relay circuit Output board 115 VAC DO 13 Output board DO 13 28 28 27 27 M10 M10 Neutral Neutral 115V DV MCB Replacement If an MCB board is defective and must be replaced, the proper controller software must be loaded into the replacement MCB. This can be done either at the factory or at the building site–if a PC equipped with appropriate Monitor software is available. The factory will download the proper controller software into a replacement MCB board before it is shipped if you include the program code with the replacement MCB part order. If the program code is not provided, the MCB board will be shipped without software. 34 Job-specific Monitor software includes each unit and auxiliary controller’s program. Therefore, it is possible to download the proper controller software to a replacement MCB at the building site if a PC equipped with that job’s Monitor software is available. In addition, if the controller’s configuration data was stored on the PC hard drive prior to the MCB failure, the exact configuration data (including all keypad programmable set points and parameters) can be restored. Refer to the user’s manual supplied with the Monitor software for more information. IM 549 Connecting the Communications Trunk Table 14. Network communications field wiring terminals Network Comm. Field Terminal Controller CSC Reciprocating Chiller Screw Chiller Table 13. Port B voltages: AMP type connector Port B (RS-485) Signal Terminal Acceptable Voltage Reading + Ground 4 3 5 3.0 +- 0.3 Vdc 2.0 +- 0.3 Vdc 0.0 +- 0.2 Vdc IM 549 Ground T11-B+ TB7-138 TB4-54 T11-B– TB7-137 TB4-53 T11-GND TB7-139 TB4-55 Figure 18. AMP connector terminal configuration 3 4 2 6 1 3 1 6 3 4 1 2 5 Fuse 1. Verify that there is no voltage between any conductor and ground. Use a voltmeter to test for voltage at the field wiring terminal block or directly on the port B connector of the level-1 controller. With one lead on the control panel chassis (ground), check for voltage at the “+,” “-,” and “ground” terminals. There should be no AC or DC voltage (see the Signal and Terminal columns of Table 3). If the conductors are properly terminated, this check will test for stray voltage throughout the trunk. Note: If you get a 2 or 3 Vdc reading, it indicates that one or more powered controllers are connected to the trunk. These controllers should be located and disconnected. 2. Verify that there are no shorts between any two conductors. Use an ohmmeter to test for shorts at field wiring terminal block or directly on the port B connector of the level-1 controller. For the three combinations of conductor pairs, there should be infinite resistance between the conductors. If the conductors are properly terminated, this check will test for shorts throughout the trunk. Note: If you find a resistance that is high but less than infinite, it indicates that one or more non-powered controllers are connected to the trunk. These controllers should be located and disconnected. 3. Verify that the communications wiring is continuous over the trunk and that the field terminations are correct. (This step is optional but recommended; to do it, you must know the physical layout of the network’s communications trunk.) Go to the last controller on one end of the daisy-chain and place a jumper across the “+” to “ground” and “-” to “ground.” Remove the jumper and repeat this step for the other two conductor pairs: “+” to “ground” and “-” to “ground.” If there is continuity for each conductor pair, the wiring is continuous and it is likely (but not guaranteed) that the terminations are correct throughout the trunk. If there is no continuity for one or more conductor pairs, there may be a break in the trunk or the terminations at one or more controllers may have been mixed up. – 4 The network communications cable should have been installed in accordance with the instructions in the “Field Wiring” section of this manual. This procedure will verify that there are no shorts or stray voltages anywhere in the communications trunk. Before beginning, verify that the port B connectors are disconnected from every controller on the trunk. + 2 Communications cable check 5 Use the following three procedures to connect the chiller controllers to the network. Port A Port B Communications [Fuse: Bussman MCR-1/4] Level-1 controller connection In order for the chillers and other level-2 controllers in a network to connect and communicate with the level 1 controller, the level 1 controller is connected first. 1. Set the network address to 00 (level 1). See “Addressing the Controllers” above for more information. 2. Push the circuit breaker (CB1) button to power up the CSC and verify that there is power to the MCB by observing the LEDs. 3. Check the voltages of port B on field wiring terminals (TB2). Use a DC voltmeter to test for proper voltages. With the ground lead on the control panel chassis (ground), check the voltage at the “+,” “-,” and “ground” terminals. Refer to Table 13 for the correct voltage levels. If no voltage or improper voltage levels are found, verify that the panel is energized. 4. Plug the network communications AMP connector into port B. Level-2 controller connection This procedure will verify that proper communications have begun for each controller as it is connected to the network. You can connect the level-2 controllers in any order; however, it is better to follow the daisy-chain as you proceed. This will make troubleshooting easier if communications problems occur. As a result of the previous procedures, the network communications connector should be disconnected from the B port at every controller on the trunk except for the level 1 controller. Be sure that this is true before beginning this procedure. For communications to occur, each networked controller must have the proper hex switch setting and the proper voltages at its port B terminals. 1. Set the network address (hex switch setting) to match the address on the engineering schedule. Each controller must have a unique address. 35 2. Turn on power to the level-2 controller. Refer to the controller installation manuals for information on how to turn on power to each controller. 3. Check the voltages of port B directly on the AMP connector. The trunk must not be connected to the controller when you do this. Use a DC voltmeter to test for proper voltages. With the ground lead on the control panel chassis (ground), check the voltage at the “+,” “-,” and “ground” terminals. Refer to Table 13 for the correct voltage levels. If no voltage or improper voltage levels are found, verify that the controller is energized. 4. Check for proper communication trunk voltages at the field wiring terminals (if any) or directly on the connector. The trunk must not be connected to the controller when you do this. If no voltage or improper voltages are found, check the wiring between the port terminals and the field terminals (if any). using Table 13 and Figure 22, verify that the three conductors are properly terminated in the network communications connector. If there is still a problem, verify that the level-1 controller is energized and that the communications trunk wiring is intact. 5. Plug the network connector into port B. 6. Verify communications have begun between the level 1 controller and the level-2 controller: To verify communications using Monitor for Windows software, network diagnostics must be performed. To run network diagnostics, select the pull-down menu “Comm.” Select “Network Diagnostic,” which will then display the “Network Diagnostics Parameters Setup” dialog box. Using the “Network Diagnostics Parameters Setup” dialog box, you can choose to continually loop the diagnostics, or have a single sweep of each controller being connected to the network. You can also perform the following functions: ● ● Display Program ID and status Restrict display of level-3s to units with errors ● ● Clear communications errors if found Log errors to file As the different controllers are connected to the network, their information is displayed on the Network Diagnostic Error Display screen. By looking at the headings labeled “Address” and “Error Codes,” network communications to a particular controller can be verified. If there are no error codes, network communications to the controller was successful. If the “Error Code” reads “Does not respond,” a communications problem has occurred. For more on network diagnostics, see “Chapter 5-Comm Menu” in “MicroTech Monitor for Windows” user’s manual. If a communications problem occurred, check the following items: ● ● ● ● Make sure the hex switches on each controller are set to the correct values. Make sure the controller has power supplied to it. Make sure the communication line is properly connected to port B. Make sure the controller is level 2 by directly connecting the PC to it. (You must know how to change communications passwords to do this.) 7. Go to the next controller and repeat steps 1 through 6. Do this for each controller being connected to the network. Note: To verify communications more quickly and easily, use two people in the commissioning of the network. Because some jobs have units located throughout a building, having one person perform the commissioning procedure may be difficult. When there are two people, one person can stay at the PC connected to the level-1 controller and the other person can go to each individual unit controller. Using a radio or other two-way communication equipment, they can indicate when a specific controller is connected and whether communications between the controllers is occurring. Keypad Key Functions The MicroTech keypad consists of twelve pressure sensitive membrane switches (Refer to Figure 11). These keys are used to step through, access, and manipulate the information in the MicroTech controller tree structure. The keypad keys are divided into four groups with two or four keys in each. Keypad password When changing any menu item entry, the user is prompted to enter the password. The change will not be allowed until the correct password is entered. The password for ALS and PFS units is always the successive pressing of the following “ACTION” group keys: “ENTER” “ENTER” “ENTER” “ENTER” Once this has been done, the user can make changes to menu item entries. After entering the correct password, the controller will allow a 5 minute time period during which the operator may make any necessary set point adjustments. Any keypad activity will reset the timer for the full 5 minutes so the password only needs to be entered once per session. After 5 minutes of inactivity, the password access time will expire providing protection against unauthorized users. 36 Category group The keys in this group provide quick access to strategic menus throughout the menu tree structure. This reduces the need to step through all the menus, one by one, in order to reach the desired menu. A. STATUS — Pressing the “STATUS” key at any time shifts the display to Menu #1 (Unit Status) which is the first menu of the STATUS category. B. CONTROL — Pressing the “CONTROL” key at any time shifts the display to Menu #13 (Control Mode) which is the first menu of the CONTROL category. C. ALARMS — Pressing the “ALARMS” key at any time shifts the display to Menu #24 (Circ 1 Current Alarm) which is the first menu of the ALARMS category. D. SWITCH — Pressing the “SWITCH” key at any time toggles the display between the current menu (status/ control) item and the related menu (control/status) item somewhere else in the tree structure. For example, if this key is pressed while the current menu item is menu item 4A (Leaving Evaporator=), the display shifts to menu item 14A (Leaving Evaporator Set point=). This provides for easy review of actual versus set point values. IM 549 Menu group The keys in this group are for stepping from menu to menu in the menu tree-structure. A. PREV. — Pressing “PREV.” shifts the display to the previous menu. Note: When Menu #1 is currently in the display (the first menu in the menu tree structure), pressing “PREV.” causes an “end of menus” message to appear in the display. Pressing “PREV.” again causes the display to wrap around to Menu #27 (the last menu in the tree structure). B. NEXT — Pressing “NEXT” shifts the display to the next menu. Note: When menu #27 is currently in the display (the last menu in the menu tree structure), pressing “NEXT” causes an “end of menus” message to appear in the display. Pressing “NEXT” again causes the display to wrap around to Menu #1 (the first menu in the menu tree structure). A. INCR. — When changing the value of a menu item entry, pressing “INCR. +” shifts the menu item display line to the next higher value or next available selection. B. DECR. — When changing the value of a menu item entry, pressing “DECR.-” shifts the menu item display line to the next lower value or previous available selection. C. ENTER — Once a change has been made to a desired value, pressing “ENTER” locks in the new value. D. CLEAR — Pressing “ALARMS” followed by “CLEAR” clears the current alarm. Also, when a change is made to a menu item, pressing “CLEAR” returns the display to the original value as long as “ENTER” has not yet been pressed. Note: The cause of an alarm should always be determined and corrected before clearing the alarm through the keypad. Example of keypad operation Item group The keys in this group are for stepping from item to item within a menu. A. PREV. — Pressing “PREV.” shifts the display to the previous item in a menu. Note: When the first item in a menu is currently in the display, pressing “PREV.” causes an “end of items” message to appear in the display. Pressing “PREV.” again causes the display to wrap around to the last item in the menu. B. NEXT — Pressing “NEXT” shifts the display to the next item in a menu. Note: When the last item in a menu is currently in the display, pressing “NEXT” causes an “end of items” message to appear in the display. Pressing “NEXT” again causes the display to wrap around to the first item in the menu. Action group The keys in this group are for making changes to unit control parameters or for clearing alarm conditions. Note: Before a change to a parameter can be made or before an alarm can be cleared, the display prompts the user with an “Enter Password” message. At this point, the password must be entered before the user can continue with the action. As an example of using the keypad key functions, consider reprogramming the Leaving Evaporator Set point from 44°F to 42°F. This consists of changing the menu item 14A (Leaving Evaporator Set point) entry from “44°F to 42°F.” Assume menu #1 (Unit Status) is currently in the display. The following key sequence is followed: 1. Press the “CATEGORY” group “CONTROL” key one time. This switches the display to menu #13 (the first menu in the “CONTROL” category). 2. Press the “MENU” group “NEXT” key once. This shifts the display to menu item 14A. (Leaving Evaporator Set point). 3. Press the “ACTION” group “DEC-” key one time. This prompts the user to enter the password. (“Enter”, “Enter”, “Enter”, “Enter”). 4. After the “Password Verified” message, press the “ACTION” group “DEC-” key four times. This changes the menu item entry to 42°F. 5. Press the “ACTION” group “ENTER” key one time. This stores the new entry into the MicroTech controller memory. 6. Pressing the “CATEGORY” group “STATUS” key then shifts the display back to menu #1. (“Enter”, “Enter”, “Enter”, “Enter”.) Personal Computer Specification For McQuay Monitor Software 1. IBM PC or 100% true compatible, 486DX or better including: a. 3 1⁄2" 1.44 MB floppy diskette drive — utilized for loading the MicroTech Monitor program into the hard disk of the computer. Also provides capability of archiving historical data and system back-up. b. 8 Megabyte RAM (Random Access Memory) — The computer must have 8 Megabytes in order to run the MicroTech Monitor Program. c. Asynchronous Serial Communications Adapter — A direct communications interface connection between the PC and the MicroTech Controller. The communications port must be recognized as COM1 or COM2 and the connector should be a 9 Pin Male. d. Super VGA Graphics Adapter — For high resolution graphics and data display. e. Parallel Printer Port — For hard-copy custom reports of all accumulated data. IM 549 f. Bus mouse or trackball. g. Hard Disk Drive (120 Megabyte min.) — A mass data storage area for the operator interface and custom report software. h. 101 Enhanced Keyboard — Required for more advanced functions of the operator interface and custom report software. i. The computer shall include MS-DOS 6.2 or greater, Windows 3.1 or greater and all owner’s manuals. j. The computer shall have an internal time clock that is battery backed to maintain system time and date. k. The computer shall have an internal, 9600-Baud, Hayes compatible modem if remote access and monitoring of the MicroTech unit controller is desired. The modem shall be addressable as Com1 or Com2. 37 2. Multisync Super VGA Color Monitor — For use with the Super VGA graphics. 3. Printer, 192 CPS (Characters Per Second) Epson LQ-510 or equivalent. Must have the ability of supporting IBM extended character graphics. 4. PrinterCable, 6 Ft. Parallel — For communications connection between the PC and the printer. The computer is used for changing set points, monitoring data, trend logging, diagnostics, and remotely clearing alarms within the MicroTech system. The computer is normally a dedicated personal computer, however, the operator may choose to exit the Monitor program from time to time to perform other functions such as word processing or data manipulation using a spreadsheet program. It should be noted, however, that for maximum convenience and functionality, the computer should be considered a dedicated computer for the MicroTech system. The communications cable from the unit control panel to the personal computer is shielded, twisted pair wire (Belden #8761 or equal). The communications adheres to the industry standards of RS-232C and the rate of communications is 9600 baud. The recommended maximum distance from the personal computer to the control panel is 50 feet. If the required distance is in excess of 50 feet, an optional RS-232 extension kit is required (contact McQuay). A voice quality, direct dial telephone line is required in remote access and monitoring of the unit controller is desired. The phone line should be terminated with a standard RJ-11C modular phone plug. MicroTech Menu Structure A complete listing of the information stored in the MicroTech controller tree structure is shown in the following tables. This table shows the menu numbers and names along with their corresponding menu items and menu item entries as they appear on the MicroTech display. The # symbol is used where the controller would normally display a numerical value. Also included in this figure is the corresponding switch menu for each menu item. Notes: 1. Status Category — Where more than one menu item entry is listed under a menu item, the list includes all the entries which can appear in the display for the particular item. The entry that shows in the display depends on the operating status of the unit. 2. Control Category — Where more than one menu item entry is listed under a menu item, the list includes all the choices from which the user can select. The selected entry appears in the display. 3. Alarm Category — The entries listed include all the possible alarm messages. The display reads the alarm conditions which occur. Status menus Provide chiller operating information as and display of sensor readings. The items listed under these status menus are affected by the settings under the associated control menus and are not directly adjusted via the keypad. Control menus All adjustable control parameters and set points, time schedules, control options and alarm thresholds are accessed through these menus. ! CAUTION Any changes to these parameters must be determined and implemented by qualified personnel with a thorough understanding of how these parameters affect the operation of the unit. Negligent or improper adjustment of these controls may result in damage to the unit or personal injury. Alarm menus Display any alarm conditions which may be present in the unit. All alarm messages are accompanied by the date and time when the alarm occurred. 38 IM 549 Menus for Two (2) Screw Compressors Units Menu 1. Chiller status Screen 1 2 3 4 Menu 4. Water temp’s Display OFF: Manual Mode System Sw Remote Comm Remote Sw Time Clock Alarm PumpDnSw’s Starting WaitForLoad CoolStageDn CoolStageUp CoolStaging # Manual Cool InterStg=xxx sec Hold Stage min Hi Loop Temp= Menu 2. Circ #1 status Screen 1 Screen 1 2 3 4 Menu 5. Circ #1 pres’s Screen 1 Display OFF: SystemSw ManualMde Alarm PumpDwnSw CycleTime xx WaitFlooded waitFlodded xxx Ready PumpingDown Starting Pre-Purge Opened EXV LowAmbStart Cooling %Cap=xxx 2 3 4 5 6 1 Display OFF: SystemSw ManualMde Alarm PumpDwnSw CycleTime xx WaitFlooded waitFlodded xxx Ready PumpingDown Starting Pre-Purge Opened EXV LowAmbStart Cooling %Cap=xxx Screen 1 2 3 4 5 6 Display Evap= xxx.x psi(kPa) xx oF (o C) Evap 145 +psi(kPa) **o F (oC) Open N/A ** F (C) Short N/A **F Cond xxx.x psi (kPa) xxxo Cond 450+ psi (kPa) xxxo Open N/A ** F (C) Short N/A **F MinCondPr = 0# MaxCondPr = 0# EXV Position= xxx Cond Fan Stage = x Menu 7. Circ #1 Temp’s Screen 1 2 3 4 5 6 7 IM 549 Display Evap= xxx.x psi(kPa) xx oF (o C) Evap 145 +psi(kPa) **o F (oC) Open N/A ** F (C) Short N/A **F Cond xxx.x psi (kPa) xxxo Cond 450+ psi (kPa) xxxo Open N/A ** F (C) Short N/A **F MinCondPr = 0# MaxCondPr = 0# EXV Position= xxx Cond Fan Stage = x Menu 6. Circ #2 pres’s Menu 3. Circ #2 status Screen Display Lvg Evap= xxx.x o F (oC) Short o F (oC) Open o F (oC) Ent Evap= xxx.x o F (oC) Short o F (oC) Open o F (oC) Ent Cond= xxx.x oF ( oC) Short o F (oC) Open o F (oC) Lvg Cond= xxx.x o F (oC) Short o F (oC) Open o F (oC) Display Satur Evap=xxxo F (o C) N/A ** oF (o C) SuctLine = xxx.xo F (oC) Open oF (o C) Short o F (oC) Super Ht =xxx.x oF (o C) N/A ** oF (o C) Satur Cond = xxxo F (o C) N/A ** oF (o C) Liquid Ln = xxx.xo F (oC) N/A ** oF (o C) SubCoolg= xxx.xo F (o C) N/A ** oF (o C) Dscharge=xxx.x oF (o C) Open o F (oC) Short o F (oC) 39 Menu 8. Circ #2 temp’s Menu 10. Comp run hours Screen Display Screen Satur Evap=xxxo F (o C) N/A ** oF (o C) SuctLine = xxx.xo F (oC) Open oF (oC) Short Super Ht =xxx.x oF (o C) N/A ** oF (o C) Satur Cond = xxxo F (o C) N/A ** oF (o C) Liquid Ln = xxx.xo F (oC) N/A ** oF (o C) SubCoolg= xxx.xo F (o C) N/A ** oF (o C) Dscharge=xxx.x oF (o C) Open o F (oC) Short oF ( oC) 1 2 3 4 5 6 7 1 2 3 4 5 6 7 8 9 10 Menu 11. Compr starts Screen 1 2 Display #1 Total=xxxxxx #2 Total=xxxxxx Menu 12. Air temp Menu 9. Chiller amps Screen 1 Display #1Total=xxxxxx #2Total=xxxxxx #1 @ 25%=xxxxxx #1 @ 50%=xxxxxx #1 @ 75%=xxxxxx #1 @100%=xxxxxx #2 @ 25%=xxxxxx #2 @ 50%=xxxxxx #2 @ 75%=xxxxxx #2 @100%=xxxxxx Display Screen PercentRLA=xxx% 1 Display OutDoor = xxx.x oF( oC) Menu 13. Control mode Screen 1 2 Display Factory Set Point Manual Unit Off Automatic Manual Staging Service Testing Manual Stage=xx Range Manual Unit Off 0 1-8 Menu 14a. Lvg evap spts — values for R-22 refrigerant Screen 1 2 3 4 5 6 7 8 9 10 11 12 13 Note: 40 Display Actv Spt=xxx.x o F (o C) Lvg Evap=xxx.x oF ( oC) CntrlBand x.x oF ( oC) StartUpD-T= x.x o F (oC) ShutDn D-T= x.x o F (o C) MaxPullDn= x.x oF ( oC) ResetOpt=None Return 4-40 Ma Network Ice Outdoor ResetSig= xx.xma MaxChWRst=xx.x o F (o C) ReturnSpt= xx.x o F (oC) OatBegRst= xx.x o F (o C) OatMaxRst= xx.x o F (oC) HiChWTmp= xxx.x o F (o C) Factory Set Point 44 3.0 3.0 1.5 0.5 (6.7) (1.6) (1.6) (0.8) (0.2) Range Not Changeable 10-80 (-12.2-26.7) 1.0-5.0 (0.5-2.7) 1.0-5.0 (0.5-2.7) 0.0-3.0 (0.0-1.6) 0.1-1.0 (0.0-0.5) None 10.0 54.0 75.0 60.0 60.0 (5.5) (12.3) (23.9) (15.5) (15.5) Not Changeable 0.0-45.0 (0.0-25.0) 15.0-80.0 (-9.4-26.7) 0.0-90.0 ([-17.8]-32.2) 0.0-90.0 ([-17.8]-32.2) 20.0-90.0 (-6.6-32.2) ( ) indicates Centigrade values; [ ] the minus sign is not displayed with three digit numbers IM 549 Menu 14b. Lvg evap spts — values for 134a refrigerant Screen 1 2 3 4 5 6 7 8 9 10 11 12 13 Display Actv Spt=xxx.x oF (o C) Lvg Evap=xxx.x o F (oC) CntrlBand x.x o F (oC) StartUpD-T= x.x o F (o C) ShutDn D-T= x.x o F (o C) MaxPullDn= x.x o F (oC) ResetOpt=None Return 4-40 Ma Network Ice Outdoor ResetSig= xx.xma MaxChWRst=xx.x o F (o C) ReturnSpt= xx.x o F (o C) OaTBegRst= xx.x o F (oC) OatMaxRst= xx.x o F (o C) HiChWTmp= xxx.x o F (o C) Factory Set Point 44 3.0 3.0 1.5 0.5 (6.7) (1.6) (1.6) (0.8) (0.2) Range Not Changeable 10-80 (-6.6-26.7) 1.0-5.0 (0.5-2.7) 1.0-5.0 (0.5-2.7) 0.0-3.0 (0.0-1.6) 0.1-1.0 (0.0-0.5) None 10.0 54.0 75.0 60.0 60.0 (5.5) (12.3) (23.9) (15.5) (15.5) Not Changeable 0.0-45.0 (0.0-25.0) 15.0-80.0 (-9.4-26.7) 0.0-90.0 (-3.9-32.2) 0.0-90.0 ([-17.8]-32.2) 20.0-90.0 (-6.6-32.2) Note: ( ) indicates Centigrade values; [ ] the minus sign is not displayed with three digit numbers Menu 15. Soft load spts Screen 1 2 3 4 Display Time Left= xxmin SoftLoad= xx min SoftLdMaxStg= x LoadDelay= xxsec Factory Set Point 20 7 15 Range 0-254 1-8 0-254 Menu 16. Compressor spt Screen 1 2 3 4 Display LeadCircuit=Auto InterStg= xxx sec MinST-ST=xx min MinSP-ST xx min Factory Set Point Auto 210 15 5 Range #1-#2 60-480 5-40 3-30 Menu 17a. Head pres spt — values for R-22 refrigerant Screen 1 2 3 4 5 6 Display MinLift 25%=xxx MinLift 50%=xxx MinLift100%=xxx DeadBandMult= x.x StageUpErr= xxx StageDnErr = xxx Factory Set Point 70 (483) 80 (552) 140 (966) 1.0 400 (2760) 100 (690) Range 60-100 (414-690) 70-100 (483-690) 100-140 (690-966) .8-1.3 300-990 (2070-6830) 50-400 (340-2760) Notes: ( ) indicates Centigrade values Menu 17b. Head pres spt — values for 134a refrigerant Screen 1 2 3 4 5 6 Display MinLift 25%=xxx MinLift 50%=xxx MinLift100%=xxx DeadBandMult= x.x StageUpErr= xxx StageDnErr = xxx Factory Set Point 50 (345) 56 (386) 90 (621) 1.0 400 (2760) 100 (690) Range 40-60 (276-414) 50-80 (345-552) 80-122 (552-841) .8-1.3 300-990 (2070-6830) 50-400 (340-2760) Notes: ( ) indicates Centigrade values Menu 18. Demand limits Screen Display Factory Set Point Range 1 Demand Lim= xstg 3 Not Changeable at this screen 2 DemandSg= xx.x ma Actual Value Indicates the Magnitude of the Demand Limit Signal Menu 19. Time/date Screen 1 2 IM 549 Display Time= xx:xx:xx Mon xx/xx/xx Factory Set Point Range Actual Time Actual Day and Date 41 Menu 20. Schedule Screen 1 2 3 4 5 6 7 8 9 10 Display Override= xx.xx hr NMPSchedule= N/A Sun 00:00-23:59 Mon 00:00-23:59 Tue 00:00-23:59 Wed 00:00-23:59 Thu 00:00-23:59 Fri 00:00-23:59 Sat 00:00-23:59 Hol 00:00-23:59 Factory Set Point 0.00 Hr N/A 00:00-23:59 00:00-23:59 00:00-23:59 00:00-23:59 00:00-23:59 00:00-23:59 00:00-23:59 00:00-23:59 Range 00:00-63.50 1-32 00:00-23:59 00:00-23:59 00:00-23:59 00:00-23:59 00:00-23:59 00:00-23:59 00:00-23:59 00:00-23:59 Menu 21. Holiday date Screen 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 Display #1 Date = N/A 0 #1 Dur = 0 Day(s) #2 Date = N/A 0 #2 Dur = 0 Day(s) #3 Date = N/A 0 #3 Dur = 0 Day(s) #4 Date = N/A 0 #4 Dur = 0 Day(s) #5 Date = N/A 0 #5 Dur = 0 Day(s) #6 Date = N/A 0 #6 Dur = 0 Day(s) #7 Date = N/A 0 #7 Dur = 0 Day(s) #8 Date = N/A 0 #8 Dur = 0 Day(s) #9 Date = N/A 0 #9 Dur = 0 Day(s) #10 Date = N/A 0 #10 Dur = 0 Day(s) #11 Date = N/A 0 #11 Dur = 0 Day(s) #12 Date = N/A 0 #12 Dur = 0 Day(s) #13 Date = N/A 0 #13 Dur = 0 Day(s) #14 Date = N/A 0 #14 Dur = 0 Day(s) Factory Set Point N/A 0 N/A 0 N/A 0 N/A 0 N/A 0 N/A 0 N/A 0 N/A 0 N/A 0 N/A 0 N/A 0 N/A 0 N/A 0 N/A 0 0 Range Jan-Dec 0-31 Jan-Dec 0-31 Jan-Dec 0-31 Jan-Dec 0-31 Jan-Dec 0-31 Jan-Dec 0-31 Jan-Dec 0-31 Jan-Dec 0-31 Jan-Dec 0-31 Jan-Dec 0-31 Jan-Dec 0-31 Jan-Dec 0-31 Jan-Dec 0-31 Jan-Dec 0-31 0 0 0 0 0 0 0 0 0 0 0 0 0 1-31 1-31 1-31 1-31 1-31 1-31 1-31 1-31 1-31 1-31 1-31 1-31 1-31 1-31 Menu 22. Service test Screen 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 42 Display #0 Output 0=Off #1 Output 1=Off #2 EXV Pos#1=xxx #3 EXV Pos#2=xxx #4 Output 4=Off #5 Output 5=Off #6 Output 6=Off #7 Output 7=Off #8 Output 8=Off #9 Output 9=Off #10 Output 10=Off #11 Output 11=Off #12 Output 12=Off #13 Output 13=Off #14 Output 14=Off #15 Output 15=Off #16 Output 16=Off #17 Output 17=Off #18 Output 18=Off #19 Output 19=Off #20 DH1=00000000 #21 DH2=00000000 #22 AI#5= x.xx Vdc Factory Set Point Off Off Off Off Off Off Off Off Off Off Off Off Off Off Off Off Off Off Range On-Off On-Off 0-760 0-760 On-Off On-Off On-Off On-Off On-Off On-Off On-Off On-Off On-Off On-Off On-Off On-Off On-Off On-Off On-Off On-Off Digital Input ( 0-Open ) ( 1-Closed ) Digital Input ( 0-Open ) ( 1-Closed ) Actual Vdc Value IM 549 Menu 23a. Alarm spts — values for R-22 refrigerant Screen 1 2 3 4 5 Display StpPumpDn =xxpsi (kPa) FullPumpDown= No FreezStat= xxpsi (kPa) FreezH2O= xx.x oF (o C) Hi Press = xxxpsi (kPa) Factory Set Point Range 34 (234) No 54 (372) 36.0 (2.3) 380 (2622) 2-54 (13-372) No-yes 20-60 (138-414) 0.0-40.0 (-17.5-4.5) 280-426 (1932-2939) Note: ( ) indicates Centigrade value Menu 23b. Alarm spts — values for 134a refrigerant Screen 1 2 3 4 5 Display StpPumpDn =xxpsi (kPa) FullPumpDown= No FreezStat= xxpsi (kPa) FreezH2O= xx.x oF (o C) Hi Press = xxxpsi (kPa) Factory Set Point Range 14 (96) No 26 (179) 36.0 (2.3) 276 (1904) 2-22 (13-151) No-yes 4-26 (27-179) 0.0-40.0 (-17.5-4.5) 180-326 (1242-2249) Note: ( ) indicates Centigrade value Menu 24. Misc setup Screen 1 2 3 4 5 6 7 8 9 8 11 13 12 13 14 15 Display Unit Type= ALS125 ALS140 ALS155 ALS170 ALS175 ALS185 ALS195 PFS150 PFS165 PFS180 PFS190 PFS200 Units = English SpeedTrol = No Power = 60 hz Port A Baud=xxxx Pre-Alarm=Blink Open Closed Alarm=Closed Blink(N/O) Blink(N/C) OAT Select=None Lcl Rmt LvgEvpAdj= 0.0 oF(o C) EntEvpAdj= 0.0 o F(o C) #1EvpAdj= 0.0psi (kPa) #2EvpAdj= 0.0psi (kPa) #1CndAdj= 0.0psi (kPa) #2CndAdj= 0.0psi (kPa) Refrigerant= R22 IDENT = SC2-X18B 1 2 3 4 5 6 7 8 9 10 IM 549 Range English No 60 9600 English-Metric No-Yes 60-50 9600-2400-1200 Blink Blink-Open-Closed Closed Closed-Blink(N/O)-Blink(N/C) None None-Lcl-Rmt -0.8-0.8 (-0.4-0.5) -0.8-0.8 (-0.4-0.5) (-13.8-13.8) (-13.8-13.8) (-13.8-13.8) (-13.8-13.8) Not Changeable Not Changeable Menu 26. #2 curr alarm Menu 25. #1 curr alarm Screen Factory Set Point Display Current Alarm @ 0:00 0/00/00 Evap = x.x psi (kPa) Cond = x.x psi (kPa) SuctLine=xxx.x oF(o C) LiquisLn=xxx.x oF(o C) Evap Lvg=xxx.x o F(oC) OA/LCnWT=xx.xxo F(oC) Capacity= xxx% Fan Stage = x Screen 1 2 3 4 5 6 7 8 9 10 Display Current Alarm @ 0:00 0/00/00 Evap = x.x psi (kPa) Cond = x.x psi (kPa) SuctLine=xxx.x o F(oC) LiquisLn=xxx.x oF(o C) Evap Lvg=xxx.x o F(oC) OA/LCnWT=xx.xxo F(oC) Capacity= xxx% Fan Stage = x 43 Menu 27. #1 Prev alarm Screen 1 2 3 4 5 6 7 8 9 10 Menu 28. #2 Prev alarm Display 1 1 2 2 3 3 4 4 5 5 Screen 1 2 3 4 5 6 7 8 9 10 Current Alarm x:xx x/xx/xx Current Alarm x:xx x/xx/xx Current Alarm x:xx x/xx/xx Current Alarm x:xx x/xx/xx Current Alarm x:xx x/xx/xx Display 1 1 2 2 3 3 4 4 5 5 Current Alarm x:xx x/xx/xx Current Alarm x:xx x/xx/xx Current Alarm x:xx x/xx/xx Current Alarm x:xx x/xx/xx Current Alarm x:xx x/xx/xx Menus for Three (3) Screw Compressors Units Menu 1. Chiller status Screen 1 2 3 4 Menu 3. Circ #2 status Display OFF: Manual Mode System Sw Remote Comm Remote Sw Time Clock Alarm PumpDnSw’s Starting WaitForLoad CoolStageDn CoolStageUp CoolStaging # Manual Cool InterStg=xxx sec Hold Stage min Hi Loop Temp= 1 44 1 Display OFF: SystemSw ManualMde Alarm PumpDwnSw CycleTime xx WaitFlooded waitFlodded xxx Ready PumpingDown Starting Pre-Purge Opened EXV LowAmbStart Cooling %Cap=xxx Display OFF: SystemSw ManualMde Alarm PumpDwnSw CycleTime xx WaitFlooded waitFlodded xxx Ready PumpingDown Starting Pre-Purge Opened EXV LowAmbStart Cooling %Cap=xxx Menu 4. Circ #3 status Screen Menu 2. Circ #1 status Screen Screen 1 Display OFF: SystemSw ManualMde Alarm PumpDwnSw CycleTime xx WaitFlooded waitFlodded xxx Ready PumpingDown Starting Pre-Purge Opened EXV LowAmbStart Cooling %Cap=xxx IM 549 Menu 5. Water temp’s Menu 9. Circ #1 temp’s Screen 1 2 3 4 Display Lvg Evap= xxx.x o F (oC) Short o F (oC) Open o F (oC) Ent Evap= xxx.x o F (oC) Short o F (oC) Open o F (oC) Ent Cond= xxx.x oF ( oC) Short o F (oC) Open o F (oC) Lvg Cond= xxx.x o F (oC) Short o F (oC) Open o F (oC) Screen 1 2 3 4 5 6 Menu 6. Circ #1 pres’s Screen 1 2 3 4 5 6 Display Evap= xxx.x psi(kPa) xx oF (o C) Evap 145 +psi(kPa) **o F (oC) Open N/A ** oF (o C) Short N/A ** oF (o C) Cond xxx.x psi (kPa) xxxo Cond 450+ psi (kPa) xxxo Open N/A ** oF (o C) Short N/A ** oF (o C) MinCondPr = 0# MaxCondPr = 0# EXV Position= xxx Cond Fan Stage = x Menu 7. Circ #2 pres’s Screen 1 2 3 4 5 6 1 2 3 4 5 6 Menu 10. Circ #2 temp’s Screen 1 2 3 4 5 Display Evap= xxx.x psi(kPa) xx oF (o C) Evap 145 +psi(kPa) **o F (oC) Open N/A ** oF (o C) Short N/A ** oF (o C) Cond xxx.x psi (kPa) xxxo Cond 450+ psi (kPa) xxxo Open N/A ** oF (o C) Short N/A ** oF (o C) MinCondPr = 0# MaxCondPr = 0# EXV Position= xxx Cond Fan Stage = x Menu 8. Circ #3 pres’s Screen 7 6 7 Screen 1 2 3 4 5 6 7 Display Satur Evap=xxxo F (o C) N/A ** oF (o C) SuctLine = xxx.xo F (oC) Open oF (o C) ShortoF ( oC) Super Ht =xxx.x oF (o C) N/A ** oF (o C) Satur Cond = xxxo F (o C) N/A ** oF (o C) Liquid Ln = xxx.xo F (oC) N/A ** oF (o C) SubCoolg= xxx.xo F (o C) N/A ** oF (o C) Dscharge=xxx.x oF (o C) Open o F (oC) Short o F (oC) Menu 12. Chiller amps Screen 1 2 3 IM 549 Display Satur Evap=xxxo F (o C) N/A ** oF (o C) SuctLine = xxx.xo F (oC) Open oF (o C) ShortoF ( oC) Super Ht =xxx.x oF (o C) N/A ** oF (o C) Satur Cond = xxxo F (o C) N/A ** oF (o C) Liquid Ln = xxx.xo F (oC) N/A ** oF (o C) SubCoolg= xxx.xo F (o C) N/A ** oF (o C) Dscharge=xxx.x oF (o C) Open o F (oC) Short o F (oC) Menu 11. Circ #3 temp’s Display Evap= xxx.x psi(kPa) xx oF (o C) Evap 145 +psi(kPa) **o F (oC) Open N/A ** oF (o C) Short N/A ** oF (o C) Cond xxx.x psi (kPa) xxxo Cond 450+ psi (kPa) xxxo Open N/A ** oF (o C) Short N/A ** oF (o C) MinCondPr = 0# MaxCondPr = 0# EXV Position= xxx Cond Fan Stage = x Display Satur Evap=xxxo F (o C) N/A ** oF (o C) SuctLine = xxx.xo F (oC) Open oF (o C) ShortoF ( oC) Super Ht =xxx.x oF (o C) N/A ** oF (o C) Satur Cond = xxxo F (o C) N/A ** oF (o C) Liquid Ln = xxx.xo F (oC) N/A ** oF (o C) SubCoolg= xxx.xo F (o C) N/A ** oF (o C) Dscharge=xxx.x oF (o C) Open o F (oC) Short o F (oC) Display #1 PrcntRLA=xxx% N/A % #2 PrcntRLA=xxx% N/A % #3 PrcntRLA=xxx% N/A % 45 Menu 13. Comp run hours Screen 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 Menu 14. Compr starts Display Screen #1Total=xxxxxx #2Total=xxxxxx #3Total=xxxxxx #1 @ 25%=xxxxxx #1 @ 50%=xxxxxx #1 @ 75%=xxxxxx #1 @100%=xxxxxx #2 @ 25%=xxxxxx #2 @ 50%=xxxxxx #2 @ 75%=xxxxxx #2 @100%=xxxxxx #3 @ 25%=xxxxxx #3 @ 50%=xxxxxx #3 @ 75%=xxxxxx #3 @1005%=xxxxxx 1 2 3 Display #1 Total=xxxxxx #2 Total=xxxxxx #3 Total=xxxxxx Menu 15. Air temp Screen 1 Display OutDoor = xxx.x oF( oC) Menu 16. Control mode Screen 1 Display Manual Unit Off Automatic Manual Staging Service Testing Factory Set Point Range Manual Unit Off Menu 17a. Lvg evap spts - values for R-22 refrigerant Screen 1 2 3 4 5 6 7 8 9 10 11 12 13 14 Display Actv Spt=xxx.x o F (o C) Lvg Evap=xxx.x oF ( oC) CntrlBand x.x oF ( oC) StartUpD-T= x.x o F (oC) ShutDn D-T= x.x o F (o C) MaxPullDn= x.x oF ( oC) ResetOpt=None Return 4-40 Ma Network Ice Outdoor ResetSig= xx.xma MaxChWRst=xx.x o F (o C) ReturnSpt= xx.x o F (oC) No OaTRst= xx.x oF ( oC) MaxOaTRst= xx.x oF (o C) HiChWTmp= xxx.x o F (o C) Amb Lock= xxx.x oF (o C) Factory Set Point 44 3.0 3.0 1.5 0.5 (6.7) (1.6) (1.6) (0.8) (0.2) Range Not Changeable 10 - 80 (-12.2 - 26.7) 1.0 - 5.0 (0.5 - 2.7) 1.0 - 5.0 (0.5 - 2.7) 0.0 - 3.0 (0.0 - 1.6) 0.1 - 1.0 (0.0 - 0.5) None 10.0 54.0 75.0 60.0 60.0 30.0 (5.5) (12.3) (23.9) (15.5) (15.5) (-1.1) Not Changeable 0.0 - 45.0 (0.0 - 25.0) 15.0 - 80.0 (-9.4 - 26.7) 0.0 - 90.0 ([-17.8] - 32.2) 0.0 - 90.0 ([-17.8] - 32.2) 20.0 - 90.0 (-6.6 - 32.2) 0.0 - 90.0 (-17.8 - 32.2) Note: [ ] the minus sign is not displayed with three digit numbers; ( ) indicates Centigrade values. 46 IM 549 Menu 17b. Lvg evap spts — values for 134a refrigerant Screen 1 2 3 4 5 6 7 8 9 10 11 12 13 14 Display Actv Spt=xxx.x oF (o C) Lvg Evap=xxx.x o F (oC) CntrlBand x.x o F (oC) StartUpD-T= x.x o F (o C) ShutDn D-T= x.x o F (o C) MaxPullDn= x.x o F (oC) ResetOpt=None Return 4-40 Ma Network Ice Outdoor ResetSig= xx.xma MaxChWRst=xx.x o F (o C) ReturnSpt= xx.x o F (o C) No OaTRst= xx.x o F (oC) MaxOaTRst= xx.x oF ( oC) HiChWTmp= xxx.x o F (o C) Amb Lock= xxx.x oF (o C) Factory Set Point 44 3.0 3.0 1.5 0.5 (6.7) (1.6) (1.6) (0.8) (0.2) Range Not Changeable 10-80 (-6.6-26.7) 1.0-5.0 (0.5-2.7) 1.0-5.0 (0.5-2.7) 0.0-3.0 (0.0-1.6) 0.1-1.0 (0.0-0.5) None 10.0 54.0 75.0 60.0 60.0 30.0 (5.5) (12.3) (23.9) (15.5) (15.5) (-1.1) Not Changeable 0.0-45.0 (0.0-25.0) 15.0-80.0 (-9.4-26.7) 0.0-90.0 (-3.9-32.2) 0.0-90.0 ([-17.8]-32.2) 20.0-90.0 (-6.6-32.2) 0.0-90.0 (-17.8-32.2) Note: [ ] the minus sign is not displayed with three digit numbers; ( ) indicates Centigrade values. Menu 18. Soft load spts Screen 1 2 3 4 Display Time Left= xxmin SoftLoad= xx min SoftLdMaxStg= x LoadDelay= xxsec Factory Set Point 20 7 15 Range 0-254 1-8 0-254 Menu 19. Compressor spt Screen 1 2 3 4 Display Lead/Lag=Auto 1->2->3 1->3->2 2->1->3 2->3->1 3->1->2 3->2->1 InterStg= xxx sec MinST-ST=xx min MinSP-ST xx min Factory Set Point Range Auto 210 15 5 60-480 5-40 3-30 Menu 20a. Head pres spt — values for R-22 refrigerant Screen 1 2 3 4 5 6 Display MinLift 25%=xxx MinLift 50%=xxx MinLift100%=xxx DeadBandMult= x.x StageUpErr= xxx StageDnErr = xxx Factory Set Point 70 (483) 80 (552) 140 (966) 1.0 400 (2760) 100 (690) Range 60-100 (414-690) 70-100 (483-690) 100-140 (690-966) .8-1.3 300-990 (2070-6830) 50-400 (340-2760) Note: ( ) indicates Centigrade values. Menu 20b. Head pres spt — values for 134a refrigerant Screen 1 2 3 4 5 6 Display MinLift 25%=xxx MinLift 50%=xxx MinLift100%=xxx DeadBandMult= x.x StageUpErr= xxx StageDnErr = xxx Factory Set Point 50 (345) 56 (386) 90 (621) 1.0 400 (2760) 100 (690) Range 40-60 (276-414) 50-80 (345-552) 80-122 (552-841) .8-1.3 300-990 (2070-6830) 50-400 (340-2760) Note: ( ) indicates Centigrade values. IM 549 47 Menu 21. Demand limits Screen Display Factory Set Point Range 1 Demand Lim= xstg 3 Not Changeable at this screen 2 DemandSg= xx.x ma Actual Value Indicates the Magnitude of the Demand Limit Signal Menu 22. Time/date Screen 1 2 Display Factory Set Point Time= xx:xx:xx Mon xx/xx/xx Range Actual Time Actual Day and Date Menu 23. Schedule Screen 1 2 3 4 5 6 7 8 9 10 Display Override= xx.xx hr NMPSchedule= N/A Sun 00:00-23:59 Mon 00:00-23:59 Tue 00:00-23:59 Wed 00:00-23:59 Thu 00:00-23:59 Fri 00:00-23:59 Sat 00:00-23:59 Hol 00:00-23:59 Factory Set Point 0.00 Hr N/A 00:00-23:59 00:00-23:59 00:00-23:59 00:00-23:59 00:00-23:59 00:00-23:59 00:00-23:59 00:00-23:59 Range 00:00-63.50 1-32 00:00-23:59 00:00-23:59 00:00-23:59 00:00-23:59 00:00-23:59 00:00-23:59 00:00-23:59 00:00-23:59 Menu 24. Holiday date Screen 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 48 Display #1 Date = N/A 0 #1 Dur = 0 Day(s) #2 Date = N/A 0 #2 Dur = 0 Day(s) #3 Date = N/A 0 #3 Dur = 0 Day(s) #4 Date = N/A 0 #4 Dur = 0 Day(s) #5 Date = N/A 0 #5 Dur = 0 Day(s) #6 Date = N/A 0 #6 Dur = 0 Day(s) #7 Date = N/A 0 #7 Dur = 0 Day(s) #8 Date = N/A 0 #8 Dur = 0 Day(s) #9 Date = N/A 0 #9 Dur = 0 Day(s) #10 Date = N/A 0 #10 Dur = 0 Day(s) #11 Date = N/A 0 #11 Dur = 0 Day(s) #12 Date = N/A 0 #12 Dur = 0 Day(s) #13 Date = N/A 0 #13 Dur = 0 Day(s) #14 Date = N/A 0 #14 Dur = 0 Day(s) Factory Set Point N/A 0 N/A 0 N/A 0 N/A 0 N/A 0 N/A 0 N/A 0 N/A 0 N/A 0 N/A 0 N/A 0 N/A 0 N/A 0 N/A 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 Range Jan-Dec 0-31 Jan-Dec 0-31 Jan-Dec 0-31 Jan-Dec 0-31 Jan-Dec 0-31 Jan-Dec 0-31 Jan-Dec 0-31 Jan-Dec 0-31 Jan-Dec 0-31 Jan-Dec 0-31 Jan-Dec 0-31 Jan-Dec 0-31 Jan-Dec 0-31 Jan-Dec 0-31 1-31 1-31 1-31 1-31 1-31 1-31 1-31 1-31 1-31 1-31 1-31 1-31 1-31 1-31 IM 549 Menu 25. Service test Screen 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 Display #0 Output 0=Off #1 Output 1=Off #2 EXV Pos#1=xxx #3 EXV Pos#2=xxx #4 EXV Pos#3=xxx #5 Output 4=Off #6 Output 5=Off #7 Output 6=Off #8 Output 7=Off #9 Output 8=Off #10 Output 9=Off #11 Output 10=Off #12 Output 11=Off #13 Output 12=Off #14 Output 13=Off #15 Output 14=Off #16 Output 15=Off #17 Output 16=Off #18 Output 17=Off #19 Output 18=Off #20 Output 19=Off #21 Output 20=Off #22 Output 21=Off #23 Output 22=Off #24 Output 23=Off #25 Output 24=Off #26 Output 25=Off #27 Output 26=Off #28 Output 27=Off #29 DH1=00000000 #30 DH2=00000000 #31 DH3=00000000 #32 AI#5= x.xx Vdc Factory Set Point Off Off Range On-Off On-Off 0-760 0-760 0-760 On-Off On-Off On-Off On-Off On-Off On-Off On-Off On-Off On-Off On-Off On-Off On-Off On-Off On-Off On-Off On-Off On-Off On-Off On-Off On-Off On-Off On-Off On-Off On-Off Digital Input ( 0-Open ) ( 1-Closed ) Digital Input ( 0-Open ) ( 1-Closed ) Digital Input ( 0-Open ) ( 1-Closed ) Actual Vdc Value Off Off Off Off Off Off Off Off Off Off Off Off Off Off Off Off Off Off Off Off Off Off Off Off Menu 26a. Alarm spts — values for R-22 refrigerant Screen 1 2 3 4 5 Display StpPumpDn =xxpsi (kPa) FullPumpDown= No FreezStat= xxpsi (kPa) FreezH2O= xx.x oF (o C) Hi Press = xxxpsi (kPa) Factory Set Point 34 (234) No 54 (372) 36.0 (2.3) 380 (2622) Range 2 - 54 (13-372) No - yes 20 - 60 (138-414) 0.0 - 40.0 (-17.5-4.5) 280 - 426 (1932-2939) Note: ( ) indicates Centigrade values Menu 26b. Alarm spts — values for 134a refrigerant Screen 1 2 3 4 5 Display StpPumpDn =xxpsi (kPa) FullPumpDown= No FreezStat= xxpsi (kPa) FreezH2O= xx.x oF (o C) Hi Press = xxxpsi (kPa) Factory Set Point 14 (96) No 26 (179) 36.0 (2.3) 276 (1904) Range 2 - 22 (13-151) No - yes 4 - 26 (27-179) 0.0 - 40.0 (-17.5-4.5) 180 - 326 (1242-2249) Note: ( ) indicates Centigrade values IM 549 49 Menu 27. Misc setup Screen 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 Display Unit Type= ALS205 ALS220 ALS235 ALS250 ALS265 ALS280 Units = English SpeedTrol = No Power = 60 hz Port A Baud=xxxx Pre-Alarm=Blink Open Closed Alarm=Closed Blink(N/O) Blink(N/C) OAT Select=None Lcl Rmt Amb Lockout= No Yes LvgEvpAdj= 0.0 o F(o C) EntEvpAdj= 0.0 o F(o C) #1EvpAdj= 0.0psi (kPa) #2EvpAdj= 0.0psi (kPa) #3EvpAdj= 0.0psi (kPa) #1CndAdj= 0.0psi (kPa) #2CndAdj= 0.0psi (kPa) #3CndAdj= 0.0psi (kPa) Refrigerant= R22 IDENT = SC32U19A Menu 28. #1 curr alarm Screen 1 2 3 4 5 6 7 8 9 10 1 2 3 4 5 6 7 8 9 10 50 Range English No 60 9600 English-Metric No-Yes 60-50 9600-2400-1200 Blink Blink-Open-Closed Closed Closed-Blink(N/O)-Blink(N/C) None None-Lcl-Rmt No No-Yes -0.8-0.8 (-0.4-0.5) -0.8-0.8 (-0.4-0.5) -2.0-2.0 (-13.8-13.8) -2.0-2.0 (-13.8-13.8) -2.0-2.0 (-13.8-13.8) -2.0-2.0 (-13.8-13.8) -2.0-2.0 (-13.8-13.8) -2.0-2.0 (-13.8-13.8) Not Changeable Not Changeable Menu 30. #3 curr alarm Display Current Alarm @ 0:00 0/00/00 Evap = x.x psi (kPa) Cond = x.x psi (kPa) SuctLine=xxx.x oF(o C) LiquisLn=xxx.x o F(o C) Evap Lvg=xxx.x oF(o C) OutsideA=xxx.x oF(o C) Capacity= xxx% Fan Stage = x Menu 29. #2 curr alarm Screen Factory Set Point Screen 1 2 3 4 5 6 7 8 9 10 Display Current Alarm @ 0:00 0/00/00 Evap = x.x psi (kPa) Cond = x.x psi (kPa) SuctLine=xxx.x oF(o C) LiquisLn=xxx.x o F(o C) Evap Lvg=xxx.x oF(o C) OutsideA=xxx.x oF(o ) Capacity= xxx% Fan Stage = x Menu 31. #1 prev alarm Display Current Alarm @ 0:00 0/00/00 Evap = x.x psi (kPa) Cond = x.x psi (kPa) SuctLine=xxx.x oF(o C) LiquisLn=xxx.x o F(o C) Evap Lvg=xxx.x oF(o C) OutsideA=xxx.x oF(o C) Capacity= xxx% Fan Stage = x Screen 1 2 3 4 5 6 7 8 9 10 Display 1 1 2 2 3 3 4 4 5 5 Current Alarm x:xx x/xx/xx Current Alarm x:xx x/xx/xx Current Alarm x:xx x/xx/xx Current Alarm x:xx x/xx/xx Current Alarm x:xx x/xx/xx IM 549 Menu 32. #2 prev alarm Screen 1 2 3 4 5 6 7 8 9 10 Menu 33. #3 prev alarm Display 1 1 2 2 3 3 4 4 5 5 Current Alarm x:xx x/xx/xx Current Alarm x:xx x/xx/xx Current Alarm x:xx x/xx/xx Current Alarm x:xx x/xx/xx Current Alarm x:xx x/xx/xx Screen 1 2 3 4 5 6 7 8 9 10 Display 1 1 2 2 3 3 4 4 5 5 Current Alarm x:xx x/xx/xx Current Alarm x:xx x/xx/xx Current Alarm x:xx x/xx/xx Current Alarm x:xx x/xx/xx Current Alarm x:xx x/xx/xx Menus for Four (4) Screw Compressors Units Menu 1. Chiller status Screen 1 2 3 4 Menu 3. Circ #2 status Display OFF: Manual Mode System Sw Remote Comm Remote Sw Time Clock Alarm PumpDnSw’s Starting WaitForLoad CoolStageDn CoolStageUp CoolStaging # Manual Cool InterStg=xxx sec Hold Stage min Hi Loop Temp= 1 IM 549 1 Display OFF: SystemSw ManualMde Alarm PumpDwnSw CycleTime xx WaitFlooded waitFlodded xxx Ready PumpingDown Starting Pre-Purge Opened EXV LowAmbStart Cooling %Cap=xxx Display OFF: SystemSw ManualMde Alarm PumpDwnSw CycleTime xx WaitFlooded waitFlodded xxx Ready PumpingDown Starting Pre-Purge Opened EXV LowAmbStart Cooling %Cap=xxx Menu 4. Circ #3 status Screen Menu 2. Circ #1 status Screen Screen 1 Display OFF: SystemSw ManualMde Alarm PumpDwnSw CycleTime xx WaitFlooded waitFlodded xxx Ready PumpingDown Starting Pre-Purge Opened EXV LowAmbStart Cooling %Cap=xxx 51 Menu 5. Circ #4 status Screen 1 Menu 9. Circ #3 pres’s Display Screen OFF: SystemSw ManualMde Alarm PumpDwnSw CycleTime xx WaitFlooded waitFlodded xxx Ready PumpingDown Starting Pre-Purge Opened EXV LowAmbStart Cooling %Cap=xxx 1 2 3 4 5 6 Menu 10. Circ #4 pres’s Screen Menu 6. Water temp’s Screen 1 2 3 4 Display 1 Lvg Evap= xxx.x o F (oC) Short oF ( oC) Open o F (oC) Ent Evap= xxx.x oF ( oC) Short oF ( oC) Open o F (oC) Ent Cond= xxx.x oF (o C) Short oF ( oC) Open o F (oC) Lvg Cond= xxx.x oF ( oC) Short oF ( oC) Open o F (oC) 2 3 4 5 6 Screen Screen 3 4 5 6 1 Display o 2 o Evap= xxx.x psi(kPa) xx F ( C) Evap 145 +psi(kPa) **o F (oC) Open N/A ** oF (o C) Short N/A ** oF (o C) Cond xxx.x psi (kPa) xxxo Cond 450+ psi (kPa) xxxo Open N/A ** oF (o C) Short N/A ** oF (o C) MinCondPr = 0# MaxCondPr = 0# EXV Position= xxx Cond Fan Stage = x 2 3 4 5 6 7 Menu 8. Circ #2 pres’s Screen 1 2 3 4 5 6 Display Evap= xxx.x psi(kPa) xxo F (o C) Evap 145 +psi(kPa) **o F (oC) Open N/A ** oF (o C) Short N/A ** oF (o C) Cond xxx.x psi (kPa) xxxo Cond 450+ psi (kPa) xxxo Open N/A ** oF (o C) Short N/A ** oF (o C) MinCondPr = 0# MaxCondPr = 0# EXV Position= xxx Cond Fan Stage = x Display Satur Evap=xxxo F (o C) N/A ** oF (o C) SuctLine = xxx.xo F (oC) Open oF (oC) ShortoF ( oC) Super Ht =xxx.x oF (o C) N/A ** oF (o C) Satur Cond = xxxo F (o C) N/A ** oF (o C) Liquid Ln = xxx.xo F (oC) N/A ** oF (o C) SubCoolg= xxx.xo F (o C) N/A ** oF (o C) Dscharge=xxx.x oF (o C) Open o F (oC) Short oF ( oC) Menu 12. Circ #2 temp’s Screen 1 2 3 4 5 6 7 52 Display Evap= xxx.x psi(kPa) xxo F (o C) Evap 145 +psi(kPa) **o F (oC) Open N/A ** oF (o C) Short N/A ** oF (o C) Cond xxx.x psi (kPa) xxxo Cond 450+ psi (kPa) xxxo Open N/A ** oF (o C) Short N/A ** oF (o C) MinCondPr = 0# MaxCondPr = 0# EXV Position= xxx Cond Fan Stage = x Menu 11. Circ #1 temp’s Menu 7. Circ #1 pres’s 1 Display Evap= xxx.x psi(kPa) xxo F (o C) Evap 145 +psi(kPa) **o F (oC) Open N/A ** oF (o C) Short N/A ** oF (o C) Cond xxx.x psi (kPa) xxxo Cond 450+ psi (kPa) xxxo Open N/A ** oF (o C) Short N/A ** oF (o C) MinCondPr = 0# MaxCondPr = 0# EXV Position= xxx Cond Fan Stage = x Display Satur Evap=xxxo F (o C) N/A ** oF (o C) SuctLine = xxx.xo F (oC) Open oF (oC) ShortoF ( oC) Super Ht =xxx.x oF (o C) N/A ** oF (o C) Satur Cond = xxxo F (o C) N/A ** oF (o C) Liquid Ln = xxx.xo F (oC) N/A ** oF (o C) SubCoolg= xxx.xo F (o C) N/A ** oF (o C) Dscharge=xxx.x oF (o C) Open o F (oC) Short oF ( oC) IM 549 Menu 13. Circ #3 temp’s Menu 15. Chiller amps Screen 1 2 3 4 5 6 7 Display Screen Satur Evap=xxxo F (o C) N/A ** oF (o C) SuctLine = xxx.xo F (oC) Open oF (o C) ShortoF ( oC) Super Ht =xxx.x oF (o C) N/A ** oF (o C) Satur Cond = xxxo F (o C) N/A ** oF (o C) Liquid Ln = xxx.xo F (oC) N/A ** oF (o C) SubCoolg= xxx.xo F (o C) N/A ** oF (o C) Dscharge=xxx.x oF (o C) Open o F (oC) Short o F (oC) 1 2 Menu 16. Comp run hours Screen 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 Menu 14. Circ #4 temp’s Screen 1 2 3 4 5 6 7 Display #1&3 PctRLA=xxx% N/A % #2&4 PctRLA=xxx% N/A % Display Satur Evap=xxxo F (o C) N/A ** oF (o C) SuctLine = xxx.xo F (oC) Open oF (o C) ShortoF ( oC) Super Ht =xxx.x oF (o C) N/A ** oF (o C) Satur Cond = xxxo F (o C) N/A ** oF (o C) Liquid Ln = xxx.xo F (oC) N/A ** oF (o C) SubCoolg= xxx.xo F (o C) N/A ** oF (o C) Dscharge=xxx.x oF (o C) Open o F (oC) Short o F (oC) Display #1Total=xxxxxx #2Total=xxxxxx #3Total=xxxxxx #4Total=xxxxxx #1 @ 25%=xxxxxx #1 @ 50%=xxxxxx #1 @ 75%=xxxxxx #1 @100%=xxxxxx #2 @ 25%=xxxxxx #2 @ 50%=xxxxxx #2 @ 75%=xxxxxx #2 @100%=xxxxxx #3 @ 25%=xxxxxx #3 @ 50%=xxxxxx #3 @ 75%=xxxxxx #3 @1005%=xxxxxx #4 @ 25%=xxxxxx #4 @ 505%=xxxxxx #4 @ 75%=xxxxxx #4 @1005%=xxxxxx Menu 17. Compr starts Screen 1 2 3 4 Display #1 #2 #3 #4 Total=xxxxxx Total=xxxxxx Total=xxxxxx Total=xxxxxx Menu 18. Air temp Screen 1 Display OutDoor = xxx.x oF( oC) Menu 19. Control mode Screen 1 2 3 4 5 6 IM 549 Display Manual Unit Off Automatic Manual Staging Service Testing Manual Stage=xx Circ 1 Mode=Auto Circ 2 Mode=Auto Circ 3 Mode=Auto Circ 4Mode=Auto Factory Set Point Range Manual Unit Off 0 Auto Auto Auto Auto 1-16 Auto-Off Auto-Off Auto-Off Auto-Off 53 Menu 20a. Lvg evap spts — values for R-22 refrigerant Screen 1 2 3 4 5 6 7 8 9 10 11 12 13 14 Display Actv Spt=xxx.x o F (o C) Lvg Evap=xxx.x oF ( oC) CntrlBand x.x oF ( oC) StartUpD-T= x.x o F (oC) ShutDn D-T= x.x o F (o C) MaxPullDn= x.x oF ( oC) ResetOpt=None Return 4-40 Ma Network Ice Outdoor ResetSig= xx.xma MaxChWRst=xx.x o F (o C) ReturnSpt= xx.x o F (oC) OatBegRst= xx.x o F (o C) OatMaxRst= xx.x o F (oC) HiChWTmp= xxx.x o F (o C) Amb Lock= xxx.x oF (o C) Factory Set Point 44 (6.7) 3.0 (1.6) 3.0 (1.6) 1.5 (0.8) 0.5 (0.2) Range Not Changeable 10-80 (-12.2-26.7) 1.0-5.0 (0.5-2.7) 1.0-5.0 (0.5-2.7) 0.0-3.0 (0.0-1.6) 0.1-1.0 (0.0-0.5) None 10.0 54.0 75.0 60.0 60.0 30.0 (5.5) (12.3) (23.9) (15.5) (15.5) (-1.1) Not Changeable 0.0-45.0 (0.0-25.0) 15.0-80.0 (-9.4-26.7) 0.0-90.0 ([-17.8]-32.2) 0.0-90.0 ([-17.8]-32.2) 20.0-90.0 (-6.6-32.2) 0.0-90.0 (-17.8-32.2) Note: [ ] the minus sign is not displayed with three digit numbers ( ) indicates Centigrade values. Menu 20b. Lvg evap spts — values for 134a refrigerant Screen 1 2 3 4 5 6 7 8 9 10 11 12 13 14 Display Actv Spt=xxx.x o F (o C) Lvg Evap=xxx.x oF ( oC) CntrlBand x.x oF ( oC) StartUpD-T= x.x o F (oC) ShutDn D-T= x.x o F (o C) MaxPullDn= x.x oF ( oC) ResetOpt=None Return 4-40 Ma Network Ice Outdoor ResetSig= xx.xma MaxChWRst=xx.x o F (o C) ReturnSpt= xx.x o F (oC) OaTBegRst= xx.x o F (oC) OatMaxRst= xx.x o F (oC) HiChWTmp= xxx.x o F (o C) Amb Lock= xxx.x oF (o C) Factory Set Point 44 3.0 3.0 1.5 0.5 (6.7) (1.6) (1.6) (0.8) (0.2) Range Not Changeable 10-80 (-6.6-26.7) 1.0-5.0 (0.5-2.7) 1.0-5.0 (0.5-2.7) 0.0-3.0 (0.0-1.6) 0.1-1.0 (0.0-0.5) None 10.0 54.0 75.0 60.0 60.0 30.0 (5.5) (12.3) (23.9) (15.5) (15.5) (-1.1) Not Changeable 0.0-45.0 (0.0-25.0) 15.0-80.0 (-9.4-26.7) 0.0-90.0 (-3.9-32.2) 0.0-90.0 ([-17.8]-32.2) 20.0-90.0 (-6.6-32.2) 0.0-90.0 (-17.8-32.2) Note: [ ] the minus sign is not displayed with three digit numbers ( ) indicates Centigrade values. Menu 21. Soft load spts Screen 1 2 3 4 54 Display Time Left= xxmin SoftLoad= xx min SoftLdMaxStg= x LoadDelay= xxsec Factory Set Point 20 7 15 Range 0-254 1-8 0-254 IM 549 Menu 22. Compressor spt Screen 1 2 3 4 Display Lead/=Auto 1->2->3->4 1->3->2->4 2->1->4->3 2->4->1->3 3->4->1->2 3->1->4->2 4->3->2->1 4->2->3->1 InterStg= xxx sec MinST-ST=xx min MinSP-ST xx min Factory Set Point Range Auto 210 15 5 60-480 5-40 3-30 Menu 23a. Head pres spt — values for R-22 refrigerant Screen 1 2 3 4 5 6 Display MinLift 25%=xxx MinLift 50%=xxx MinLift100%=xxx DeadBandMult= x.x StageUpErr= xxx StageDnErr = xxx Factory Set Point 70 (483) 80 (552) 140 (966) 1.0 400 (2760) 100 (690) Range 60-100 (414-690) 70-100 (483-690) 100-140 (690-966) .8-1.3 300-990 (2070-6830) 50-400 (340-2760) Note: ( ) indicates Centrigrade values Menu 23b. Head pres spt — values for 134a refrigerant Screen 1 2 3 4 5 6 Display MinLift 25%=xxx MinLift 50%=xxx MinLift100%=xxx DeadBandMult= x.x StageUpErr= xxx StageDnErr = xxx Factory Set Point 50 (345) 56 (386) 90 (621) 1.0 400 (2760) 100 (690) Range 40-60 (276-414) 50-80 (345-552) 80-122 (552-841) .8-1.3 300-990 (2070-6830) 50-400 (340-2760) Note: ( ) indicates Centrigrade values Menu 24. Demand limits Screen Display Factory Set Point Range 1 Demand Lim= xstg 3 Not Changeable at this screen 2 DemandSg= xx.x ma Actual Value Indicates the Magnitude of the Demand Limit Signal Menu 25. Time/date Screen 1 2 Display Factory Set Point Time= xx:xx:xx Mon xx/xx/xx Range Actual Time Actual Day and Date Menu 26. Schedule Screen 1 2 3 4 5 6 7 8 9 10 IM 549 Display Override= xx.xx hr NMPSchedule= N/A Sun 00:00-23:59 Mon 00:00-23:59 Tue 00:00-23:59 Wed 00:00-23:59 Thu 00:00-23:59 Fri 00:00-23:59 Sat 00:00-23:59 Hol 00:00-23:59 Factory Set Point 0.00 Hr N/A 00:00-23:59 00:00-23:59 00:00-23:59 00:00-23:59 00:00-23:59 00:00-23:59 00:00-23:59 00:00-23:59 Range 00:00-63.50 1-32 00:00-23:59 00:00-23:59 00:00-23:59 00:00-23:59 00:00-23:59 00:00-23:59 00:00-23:59 00:00-23:59 55 Menu 27. Holiday date Screen 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 56 Display #1 Date = N/A 0 #1 Dur = 0 Day(s) #2 Date = N/A 0 #2 Dur = 0 Day(s) #3 Date = N/A 0 #3 Dur = 0 Day(s) #4 Date = N/A 0 #4 Dur = 0 Day(s) #5 Date = N/A 0 #5 Dur = 0 Day(s) #6 Date = N/A 0 #6 Dur = 0 Day(s) #7 Date = N/A 0 #7 Dur = 0 Day(s) #8 Date = N/A 0 #8 Dur = 0 Day(s) #9 Date = N/A 0 #9 Dur = 0 Day(s) #10 Date = N/A 0 #10 Dur = 0 Day(s) #11 Date = N/A 0 #11 Dur = 0 Day(s) #12 Date = N/A 0 #12 Dur = 0 Day(s) #13 Date = N/A 0 #13 Dur = 0 Day(s) #14 Date = N/A 0 #14 Dur = 0 Day(s) Factory Set Point N/A 0 N/A 0 N/A 0 N/A 0 N/A 0 N/A 0 N/A 0 N/A 0 N/A 0 N/A 0 N/A 0 N/A 0 N/A 0 N/A 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 Range Jan - Dec 0 - 31 Jan - Dec 0 - 31 Jan - Dec 0 - 31 Jan - Dec 0 - 31 Jan - Dec 0 - 31 Jan - Dec 0 - 31 Jan - Dec 0 - 31 Jan - Dec 0 - 31 Jan - Dec 0 - 31 Jan - Dec 0 - 31 Jan - Dec 0 - 31 Jan - Dec 0 - 31 Jan - Dec 0 - 31 Jan - Dec 0 - 31 1 - 31 1 - 31 1 - 31 1 - 31 1 - 31 1 - 31 1 - 31 1 - 31 1 - 31 1 - 31 1 - 31 1 - 31 1 - 31 1 - 31 IM 549 Menu 28. Service test Screen 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 Display #0 Output 0=Off #1 Output 1=Off #2 EXV Pos#1=xxx #3 EXV Pos#2=xxx #4 EXV Pos#3=xxx #5 EXV Pos#4=xxx #6 Output 4=Off #7 Output 5=Off #8 Output 6=Off #9 Output 7=Off #10 Output 8=Off #11 Output 9=Off #12 Output 10=Off #13 Output 11=Off #14 Output 12=Off #15 Output 13=Off #16 Output 14=Off #17 Output 15=Off #18 Output 16=Off #19 Output 17=Off #20 Output 18=Off #21 Output 19=Off #22 Output 20=Off #23 Output 21=Off #24 Output 22=Off #25 Output 23=Off #26 Output 24=Off #27 Output 25=Off #28 Output 26=Off #29 Output 27=Off #30 Output 28=Off #31 Output 29=Off #32 Output 31=Off #33 Output 32=Off #34 Output 33=Off #35 Output 34=Off #36 Output 35=Off #37 Output 36=Off #38 Output 37=Off #39 Output 38=Off #40 DH1=00000000 #41 DH2=00000000 #42 DH3=00000000 #43 DH4=00000000 #32 AI#5= x.xx Vdc Factory Set Point Off Off Range On-Off On-Off 0-760 0-760 0-760 0-760 On-Off On-Off On-Off On-Off On-Off On-Off On-Off On-Off On-Off On-Off On-Off On-Off On-Off On-Off On-Off On-Off On-Off On-Off On-Off On-Off On-Off On-Off On-Off On-Off On-Off On-Off On-Off On-Off On-Off On-Off On-Off On-Off On-Off On-Off Digital Input ( 0-Open Digital Input ( 0-Open Digital Input ( 0-Open Digital Input ( 0-Open Actual Vdc Value Off Off Off Off Off Off Off Off Off Off Off Off Off Off Off Off Off Off Off Off Off Off Off Off Off Off Off Off Off Off Off Off Off Off ) ) ) ) ( ( ( ( 1-Closed 1-Closed 1-Closed 1-Closed ) ) ) ) Menu 29a. Alarm spts – values for R-22 refrigerant Screen 1 2 3 4 5 Display StpPumpDn =xxpsi (kPa) FullPumpDown= No FreezStat= xxpsi (kPa) FreezH2O= xx.x oF (o C) Hi Press = xxxpsi (kPa) Factory Set Point 34 (234) No 54 (372) 36.0 (2.3) 380 (2622) Range 2-54 (13-372) No-yes 20-60 (138-414) 0.0-40.0 (-17.5-4.5) 280-426 (1932-2939) Note: ( ) indicates Centrigrade values Menu 29b. Alarm spts – values for 134a refrigerant Screen 1 2 3 4 5 Display StpPumpDn =xxpsi (kPa) FullPumpDown= No FreezStat= xxpsi (kPa) FreezH2O= xx.x oF (o C) Hi Press = xxxpsi (kPa) Factory Set Point 14 (96) No 26 (179) 36.0 (2.3) 276 (1904) Range 2-22 (13-151) No-yes 4-26 (27-179) 0.0 - 40.0 (-17.5-4.5) 180 - 326 (1242-2249) Note: ( ) indicates Centrigrade values IM 549 57 Menu 30. Misc setup Screen 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 Display Unit Type = ALS300 ALS315 ALS330 ALS340 ALS360 ALS370 ALS380 Units = English SpeedTrol = No Power = 60 hz Port A Baud=xxxx Pre-Alarm=Blink Open Closed Alarm=Closed Blink(N/O) Blink(N/C) OAT Select=None Lcl Rmt Amb Lockout= No Yes LvgEvpAdj= 0.0 o F(o C) EntEvpAdj= 0.0 o F(o C) #1EvpAdj= 0.0psi (kPa) #2EvpAdj= 0.0psi (kPa) #3EvpAdj= 0.0psi (kPa) #4EvapAdj=0.0psi (kPa) #1CndAdj= 0.0psi (kPa) #2CndAdj= 0.0psi (kPa) #3CndAdj= 0.0psi (kPa) #4CndAdj=0.0psi (kPa) Refrigerant= R22 IDENT = SC4XX19A Menu 31. #1 curr alarm Screen 1 2 3 4 5 6 7 8 9 10 1 2 3 4 5 6 7 8 9 10 58 Range English No 60 9600 English-Metric No-Yes 60-50 9600-2400-1200 Blink Blink-Open-Closed Closed Closed-Blink(N/O)-Blink(N/C) None None-Lcl-Rmt No No-Yes -0.8-0.8 (-0.4-0.5) -0.8-0.8 (-0.4-0.5) -2.0-2.0 (-13.8-13.8) -2.0-2.0 (-13.8-13.8) -2.0-2.0 (-13.8-13.8) -2.0-2.0 (-13.8-13.8) -2.0-2.0 (-13.8-13.8) -2.0-2.0 (-13.8-13.8) -2.0-2.0 (-13.8-13.8) -2.0-2.0 (-13.8-13.8) Not Changeable Not Changeable Menu 33. #3 curr alarm Display Current Alarm @ 0:00 0/00/00 Evap = x.x psi (kPa) Cond = x.x psi (kPa) SuctLine=xxx.x oF(o C) LiquisLn=xxx.x o F(o C) Evap Lvg=xxx.xoF(o C) OutsideA=xxx.x oF(o C) Capacity= xxx% Fan Stage = x Menu 32. #2 curr alarm Screen Factory Set Point Screen 1 2 3 4 5 6 7 8 9 10 Display Current Alarm @ 0:00 0/00/00 Evap = x.x psi (kPa) Cond = x.x psi (kPa) SuctLine=xxx.x oF(o C) LiquisLn=xxx.x o F(o C) Evap Lvg=xxx.x oF(o C) OutsideA=xxx.x oF(o C) Capacity= xxx% Fan Stage = x Menu 34. #4 curr alarm Display Current Alarm @ 0:00 0/00/00 Evap = x.x psi (kPa) Cond = x.x psi (kPa) SuctLine=xxx.x oF(o C) LiquisLn=xxx.x o F(o C) Evap Lvg=xxx.x oF(o C) OutsideA=xxx.x oF(o C) Capacity= xxx% Fan Stage = x Screen 1 2 3 4 5 6 7 8 9 10 Display Current Alarm @ 0:00 0/00/00 Evap = x.x psi (kPa) Cond = x.x psi (kPa) SuctLine=xxx.x oF(o C) LiquisLn=xxx.x o F(o C) Evap Lvg=xxx.x oF(o C) OutsideA=xxx.x oFo C) Capacity= xxx% Fan Stage = x IM 549 Menu 35. #1 prev alarm Screen 1 2 3 4 5 6 7 8 9 10 Menu 37. #3 prev alarm Display 1 1 2 2 3 3 4 4 5 5 Current Alarm x:xx x/xx/xx Current Alarm x:xx x/xx/xx Current Alarm x:xx x/xx/xx Current Alarm x:xx x/xx/xx Current Alarm x:xx x/xx/xx 1 2 3 4 5 6 7 8 9 10 Menu 36. #2 prev alarm Screen 1 2 3 4 5 6 7 8 9 10 IM 549 Current Alarm x:xx x/xx/xx Current Alarm x:xx x/xx/xx Current Alarm x:xx x/xx/xx Current Alarm x:xx x/xx/xx Current Alarm x:xx x/xx/xx Display 1 1 2 2 3 3 4 4 5 5 Current Alarm x:xx x/xx/xx Current Alarm x:xx x/xx/xx Current Alarm x:xx x/xx/xx Current Alarm x:xx x/xx/xx Current Alarm x:xx x/xx/xx Menu 38. #4 prev alarm Display 1 1 2 2 3 3 4 4 5 5 Screen Screen 1 2 3 4 5 6 7 8 9 10 Display 1 1 2 2 3 3 4 4 5 5 Current Alarm x:xx x/xx/xx Current Alarm x:xx x/xx/xx Current Alarm x:xx x/xx/xx Current Alarm x:xx x/xx/xx Current Alarm x:xx x/xx/xx 59 Schematics and Drawings ALS PFS Wiring Diagrams Table 15. Unit Control Cabinet Layout Wiring Legend Unit Control Stage Output MicroTech Schematic Field Wiring ALS 125A- 204A PFS 140A- 200A ALS 205A- 280A ALS 300A- 380A 717449-01 719836-01 717460-01 719869-01 704352C-01 719833C-01 704352C-01 — 716995D-01 716998D-01 718507D-01 718640D-01 716996D-01 716999D-01 718508D-01 718641D-01 716997D-01 718099D-01 718509D-01 718642F-01 719740C-01 719835C-01 719740C-01 719740C-01 Control Cabinet Layout – ALS 125A-204A FB 6 Keypad FB 7 FB 8 FB 9 FB 10 FB 11 FB 5 T1 Mech. relays GRD F1 CB F2 M11 M12 M13 M15 M23 NB ADX TB5 GD1 M24 PB 1 CT OL5 OL1 CB5 CB1 M5 M1 1 GFP R TB2 M14 OL2 OL6 CB2 CB6 M2 M6 TB3 High voltage wireway T4 T8 RES1 Fax alarm option 60 M22 PVM Low voltage wireway Low voltage wireway T2 High voltage wireway TB4 Output board GD2 Low voltage wireway Low voltage wireway Modem Low voltage wireway ADI GFP S High voltage wireway EXV M21 MDBI M25 T10 T7 C1 C2 SC IM 549 Control Cabinet Layout – ALS 205A-280A C31 FB 12 SC31 FB 13 FB 14 FB 15 FB 16 FB 17 FB 5 T1 PVM1 OB2 M 31 High voltage wireway SC41 Mech. relays EXVB2 NB OBI Low voltage wireway TB4 M 35 M 43 FB 7 FB 8 FB 9 FB 10 FB 11 M 11 M 12 M 13 M 15 M 23 M 25 M 21 M 22 M 14 M 34 M 44 M 45 M 24 CT2 TB2 OL1 OL3 OL2 OL4 CB1 CB3 CB2 CB4 M3 M2 TB5 Res1 Res2 Low voltage wireway IM 549 T 10 High voltage wireway SC 1 SC 2 Low voltage wireway GD GD R1 R2 GD GD R3 R4 T4 T8 T6 High voltage wireway Modem ADI M 33 T1 C MCB 280 F1 CB F2 DIC16 Low voltage wireway M 42 FB 6 TB3 DIOX18 Low voltage wireway AOX04 M 32 1 PB Mech. relays High voltage wireway EXVB1 M 41 GRD TB6 High voltage wireway C41 T2 T7 C1 M1 C3 C2 M4 C4 61 Control Cabinet Layout – ALS 300A-380A FB 12 FB 13 FB 14 T1 Keypad M 32 M 31 High voltage wireway M 33 M 34 FB 5 M 35 GRD EXVB2 FB 10 FB 11 M 11 M 12 M 13 M 15 M 23 M 25 M 21 M 22 High voltage wireway M 24 T 10 C T3 Low voltage wireway Low voltage wireway M 14 T2 DBI TB2 High voltage wireway C DL1 DL2 DL3 CB1 CB2 CB3 M1 M2 M3 TB5 Res1 Res2 Res3 Low voltage wireway SC 1 SC 2 SC 3 Low voltage wireway GD GD R1 R2 GD GD R3 R4 T4 T8 T6 High voltage wireway Modem FB 9 T1 ADI TB4 FB 8 C MCB 280 FB 7 NB Low voltage wireway 62 F1 CB F2 DIOX FB 6 1 PB Mech. relays AOX TB3 EXVB1 TB6 DB2 T2 T7 IM 549 Wiring legend – 0704352C-01 ALS Wiring Legend Label AB ADI AOX CI-C3 CII,C2I CBI-CB7 CB9 CBIO CHWI COMPR I-3 CSII-CS33 CTI,CT2 DS1,DS2 EXV (BRD) FI F2 FB5 FB6-FBI5 GDI-GD3 GFP GRD,GND HGR1-HGR2 HTRI-HTR3 HTR5 JI-JI3 JB5 KEYPAD LPSI-LPS3 MI-M7 MIl-M37 MCB250 MHPRI-MHPR3 MJ MODEMI MODEM2 MPRI-MPR3 MTRII-MTR37 NB OB OLI-OL7 OSI-OS3 PBI-PB3 IM 549 Description ALARM BELL ANALOG DIGITAL INPUT BOARD ANALOG OUTPUT BOARD SURGE CAPACITOR, COMPRESSOR CAPACITOR, SPEEDTROL CIRCUIT BREAKER (POWER) CIRCUIT BREAKER (MICROTECH) CIRCUIT BREAKER (FAX ALARM) CHILLED WATER INTERLOCK COMPRESSORSI-3 COMPRESSOR SOLENOID CURRENT TRANSFORMER DISCONNECT SWITCH, MAIN ELECTRONIC EXPANSlON VALVE BOARD FUSE, CONTROL CIRCUIT FUSE, COOLER HEATER FUSEBLOCK, CONTROL POWER FUSEBLOCKS, FAN MOTORS GUARDISTOR RELAY GROUND FAULT PROTECTOR GROUND HOT GAS RELAY COMPRESSOR HEATER HEATER,EVAPORATOR JUMPERS (LEAD) JUNCTION BOX, EVAP. HEATER KEYPAD SWITCH & DISPLAY LIQUID PRESENCE SENSOR CONTACTORS, COMPRESSOR CONTACTOR, FAN MOTORS MICROTECH CONTROL BOARD-250 MECH. HIGH PRESSURE RELAY MECHANICAL JUMPER MODEM, MICROTECH MODEM, FAX MOTOR PROTECTOR RELAY MOTORS, CONDENSER FANS NEUTRAL BLOCK OUTPUT BOARD, MICROTECH OVERLOADS OIL SAFETY SWITCH POWER BLOCK, MAIN Standard Location BACK OR SIDE OF CTRL BOX CTRL BOX, CTRL PANEL CTRL BOX, CTRL PANEL CTRL BOX, POWER PANEL INSIDE SPEEDTROL BOX CTRL BOX, POWER PANEL CTRL BOX, CTRL PANEL CTRL BOX, CTRL PANEL FIELD INSTALLED ON BASE RAIL ON COMPRESSOR CTRL BOX, POWER PANEL CTRL BOX, POWER PANEL CTRL BOX, CTRL PANEL CTRL BOX, SWITCH PANEL CTRL BOX, SWITCH PANEL CTRL BOX, POWER PANEL CTRL BOX, POWER PANEL CTRL BOX, CTRL PANEL CTRL BOX, POWER PANEL CTRL BOX, POWER PANEL CTRL BOX, POWER PANEL ON COMPRESSORS WRAPPED AROUND EVAP. CTRLBOX, CTRLPANEL NEAR EVAP, ON BASE RAIL CTRL BOX, KEYPAD PANEL ON COMPRESSOR CTRLBOX, POWERPANEL CTRL BOX, POWER PANEL CTRL BOX, CTRL PANEL CONTROL BOX, CTRL PANEL CTRL BOX, CTRL PANEL CTRL BOX, CTRL PANEL CTRL BOX, CTRL PANEL CONTROL BOX, CTRL PANEL CONDENSER SECTION CTRL BOX, CTRL PANEL CTRL BOX, CTRL PANEL CTRL BOX, POWER PANEL CTRL BOX, CTRL PANEL CTRL BOX, POWER PANEL Label Standard Location Description PSI-PS3 PVMI-PVM3 RES1,RES2 SI SCII,SC21,SC31 SIG.CONV(SC) SVI,SV2,SV7 SV3,SV4,SV8 SV5,SV6,SV9 TI T2, T5, T7 T3 T4,T6 TIO TB2 TB3 TB4-TB5 TBIO TD5-TD7 PUMPDOWN SWITCHES PHASE VOLTAGE MONITOR RESISTOR, CURRENT TRANSFORMER SWITCH, MANUAL START/STOP SPEED CONTROL SIGNAL CONVERTER SOLENOID VALVE, LIQ. LINES SOLENOID VALVE, LIQ. INJECTION SOLENOID VALVE, HG BYPASS TRANSFORMER, MAIN CONTROL TRANSFORMER, 120 TO 24V CONTROL TRANSFORMER, 575 TO 208-230V SPEEDTROL TRANSFORMER, 24 TO 18V CONTROL TRANSFORMER, 208-240 TO 24V OR 460 TO 24V -SPEEDTROL TERMINAL BLOCK, 120V FIELD TERMINAL BLOCK,120V TERMINAL BLOCK, CONTROL 24V OR LESS TERMINAL BLOCK, FAX ALARM TIME DELAY, COMPR. REDUCED INRUSH CTRL BOX, SWITCH PANEL CTRL BOX, POWER PANEL CTRL BOX, POWER PANEL CTRL BOX, KEYPAD PANEL INSIDE SPEEDTROL BOX CTRL BOX, CTRL PANEL ON LIQUID LINES ON COMPR LIQ. INJ. LINE ON LINE TO HOT GAS VALVE CTRL BOX, POWER PANEL CTRL BOX, CTRL PANEL CTRL BOX, CTRL PANEL CTRL BOX, CTRL PANEL CTRL BOX, CTRL PANEL CTRL BOX, CTRL PANEL CTRL BOX, CTRL PANEL CTRL BOX, CTRL PANEL CTRL BOX, CTRL PANEL CTRL BOX, CTRL PANEL WIRING SYMBOLS CABLE-TWISTED. SHIELDED AND JACKETED PAIR POWER WIRING, FACTORY INSTALLED POWER WIRING, FACTORY INSTALLED POWER WIRING, FACTORY INSTALLED OPTION BLOCK CONTROL BOX TERMINAL, FIELD CONN. USAGE CONTROL BOX TERMINAL, FACTORY USAGE THERMISTOR UNINDENTIFIED COMPONENT TERMINAL DIODE INDENTIFIED COMPONENT TERMINAL CAPACITOR WIRE NUT MOV VARISTOR MANUAL RESET, CONTROL V AUTOMATIC RESET, CONTROL 63 PFS Unit Control – 0716998D-01 64 IM 549 PFS 8-Stage Output – 071699D-01 IM 549 65 PFS MicroTech – 717000D-01 66 IM 549 ALS Unit Control – 0716995D-01 IM 549 67 ALS 8-Stage Output – 0716996D-01 68 IM 549 ALS MicroTech – 2 Compressor Unit – 716997D-01 IM 549 69 ALS Field Wiring – 0719740C-01 Disconnect (by others) Unit main terminal block GND lug 3 phase To compressor(s) and fan motors power supply Fused control circuit transformer option Disconnect (by others) NB N 10A fuse 120 VAC control power Separate evaporator heater power option TB2 1 (by others) 540 Disconnect (by others) 120 VAC (by others) N 545 If separate evaporator heater power option is used — remove wires 540 and 545. 10A fuse (by others) 13 16 24V or 120 VAC (by others) 9 N CHW pump relay (by others) Solid state relay 24V or 120 VAC 1.5 amps max. Output relay 1 10 5A TB4 4-20 MA for CHW reset (by others) + – 46 + – + Connection to RS232 for modem or direct – PC connection GND Connection to RMS – (remote monitoring sequence) + or to NMP (network master panel) GND Inherent in MicroTech controller GND 47 4-20 MA for demand limit (by others) Time clock 250 Ω load impedance 45 250 Ω load impedance 48 49 1-CLR (RS232 TR) 50 3-BLK (RS232 RC) 51 Communication port “A” 5-GND 52 3-BLK (RS485) 53 4-CLR (RS485) 54 Communication port “B” 5-GND 55 Off Auto Remote stop (by others) 60 Manual CHW flow switch (by others) 61 MJ If remote stop control is used, remove jumper from terminals 60 to 61. 62 63 Factory supplied alarm field wired Alarm bell option TB5 GND Alarm bell max 1.5 amps 102 107 70 Output relay 0 5A 24 VAC35 VA max. IM 549 PFS Field Wiring – 0719835C-01 Disconnect (by others) Unit main terminal block GND lug 3 phase power To compressor(s) supply Fused control circuit transformer option Disconnect (by others) NB N 10A fuse 120 VAC control power TB2 1 (by others) Note: For single condenser pumpstarter applications – field jumper terminals 11 & 12, then field wire single starter between terminals 11 & 16. MA MB 545 11 12 16 24V or 120 VAC (by others) 9 N CHW pump relay (by others) Solid state relay 24V or 120 VAC 1.5 amps max. Output relay 1 10 5A TB4 4-20 MA for CHW reset (by others) + – 46 + – + Connection to RS232 for modem or – direct PC connection GND Connection to RMS – (remote monitoring sequence) + or to NMP (network master panel) GND Condenser flow switch (by others) Inherent in MicroTech controller GND 47 4-20 MA for demand limit (by others) Time clock 250 Ω load impedance 45 250 Ω load impedance 48 49 50 51 52 53 54 55 1-CLR (RS232 TR) 3-BLK (RS232 RC) Communication port “A” 5-GND 3-BLK (RS485) 4-CLR (RS485) Communication port “B” 5-GND 58 59 Off Auto Remote stop (by others) 60 Manual Evap. flow switch (by others) 61 MJ If remote stop control is used, remove jumper from terminals 60 to 61. 62 63 Alarm bell (by others) TB5 GND Alarm bell max 1.5 amps 102 107 IM 549 Output relay 0 5A 24 VAC35 VA max. 71 ® 13600 Industrial Park Boulevard, P.O. Box 1551, Minneapolis, MN 55440 USA (612) 553-5330